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Additional References with Titles
Chapter 2 Y.Fukai, S.Kazama: NMR studies of anomalous diffusion of hydrogen and phase transition in
vanadium-hydrogen alloys. Acta Metall. 25, 59 (1977) O.Yoshinari, M.Koiwa, H.Asano, M.Hirabayashi: Low frequency internal friction study on
vanadium-deuterium alloys. Trans. Jpn. Inst. Met. 19, 171 (1978) B.J.Makenas: "Precipitation and Ordering in the Niobium-Hydrogen System": Ph.D. Thesis,
University of Illinois, Urbana (1978) M.Amano, Y.Sasaki: Internal friction in niobium hydride. Trans. Nat. Res. Inst. Met. 19 (4) 155
(t977) W. Pesch, T. Schober, H.Wenzl: A TEM investigation of anisotropic lattice distortions in ordered
NbH and NbD alloys. Scr. Metall. 12, 815 (1978) G.Ferron, M.Quintard: Evidence of an internal friction phase transformation peak in niobium-
hydrogen alloys. Phys. Status Solidi (a) 46, K43 (1978) H. Metzger, H. Peisl: Huang diffuse x-ray scattering from lattice strains in high-concentration Ta-H
alloys. J. Phys. F: Metal Phys. 8, 391 (1978) C.E.Laciana, A.J. Pedraza, E.J.Savino: Lattice distortion and migration energy of oxygen in
vanadium and hydrogen in niobium, tantalum and vanadium. Phys. Status Solidi (a) 45, 315 (1978)
J.Hauck: Structural relations between vanadium, niobium, tantalum hydrides and deuterides. Acta Crystallogr. A34, 389 (1978)
H.Metzger, H.Jo, S.C.Moss, D.G.Westlake: Single crystal x-ray study of the superstructure modulation and long-range order in VzD. Phys. Status Solidi (a) 17, 631 (1978)
Chapter 5 R.A. Guidotti, G.B.Atkinson, M. M. Wong: Hydrogen absorption by rare-earth transition metal
alloys. J. Less-Common Metals 52 (1), 13 (1977) S.Yajima, H.Kayano: Hydrogen sorption in LazMg17. J. Less-Common Metals 55 (1), 139 (1977) T.Takeshita, W.E.Wallace: Hydrogen absorption in Th(Ni, A1)5 ternaries. J. Less-Common
Metals 55 (1), 61 (1977) E.C.Ashby, K.C.Nainan, H.S. Prasad: Preparation of magnesium zinc hydrides, MgZnH4 and
Mg(ZnH3)z. Inorg. Chem. 16 (2), 348 (1977) Proc., 2nd World Hydrogen Energy Conf., Ztirich, 1978, ed. by T.N.Veziroglu, W.Seifritz (Perga-
mon Press, Oxford, 1978). Has 23 papers on metal hydrides and their uses Proe. Int. Syrup. on Energy Storage, Geilo, 1977, (Pergamon Press, Oxford, 1978). Has numerous
review articles by authorities in the field
Chapter 6 H. Oesterreicher, J. Clinton, H. Bittner: Hydrides of La Ni compounds. Mater. Res. Bull. 11, 1241
(t976) W. A. Lanford, P. H. Schmidt, J. M. Rowell, J. M. Poate, R. C. Dynes, P. D. Dernier: Sensitivity of the
T~ of Nb3Ge to hydrogen content. Appl. Phys. Lett. 32, 339 (1978) L. Ya. Vinnikov, O.V. Zharikov, Ch. V. Kopetskii, V. M. Polovov: Pinning in single-crystal Nb and
V containing H. Soy. J. Low. Temp. Phys. 3, 11 (1977)
332
E. F. Khodosov, V.F.Shkav: Low-temperatures (up to 15 K) conductivity of Nb H systems. J ETP Lett. 25, 313 (1977)
B.M.Klein, E.N.Enconomou, D.A.Papaconstantopoulos: Inverse isotope effect and the x dependence of the superconducting transition temperature in PdHx and PdDx. Phys. Rev. Lett. 39, 574 (1977)
A.I.Morozov: Superconductivity in two-component compounds. The isotope effect in PdH. Soy. J. Low. Temp. Phys. 3, 404 (1977)
P.Jena, C.L.Wiley, F.Y.Fradin: Isotope effect on the electronic spin density in PdH super- conductors. Phys. Rev. Lett. 40, 578 (1978)
C.B.Satterthwaite: On isotope effects in PdH(D)x. Phys. Status Solidi A43, K 147 (1978) B.N.Ganguly: "Anharmonicity and superconductivity in metal-hydrides'. Proc. 2nd Int. Congr.
H in Metals, Paris (1977) M.Gupta, A.J.Freeman: Electronic structure and proton spin-lattice relaxation in PdH. Phys.
Rev. B17, 3029 (1978) A.Gorska, A.M.Gorski, J.Igalson, A.J.Pindor, L.Sniadower: "Ideal resistivity and electron-
phonon interaction in Pd H/ ' . Proc. 2nd lnt. Congr. H in Metals, Paris (1977) T. F. Smith, G. K. White: Griineisen parameters, electron-phonon enhancement and superconducti-
vity for Pd-H alloys. J. Phys. F.: Metal Physics 7, 1029 (1977) J.C.H.Chiu, R.A.B.Devine: Electrical resistivity evidence for the correlation between super-
conductivity and optical phonons in Pd H. Solid State Commun. 22, 631 (1977) N.Jacobi, L.G.Caron: The role of optic phonons in the superconductivity of PdH and PdD.
J. Low Temp. Phys. 30, 51 (1978) L. Dumoulin, P.N6dellec, C.Arzoumanian, J.P.Burger: Optical phonons in PdH~ and PdD x by
superconducting tunneling measurements. To be published D.A.Papaconstantopoulos, E.N.Economou: Superconductivity in the Pd-Ag H system. Inst.
Phys. Conf. Ser. No. 39, 489 (1978) D. A. Papaconstantopoulos, B. M. Klein, E.N. Economou, L. L. Boyer: Band structure and super-
conductivity of PdHx and PdD x. Phys. Rev. B17, 141 (1978) A. W. Szafranski, T. Skoskiewicz, B. Baranowski: Superconductivity in the Pd 1.~MxH c ( M - noble
metal) and PdByH c alloy systems. Phys. Status Solidi A37, K 163 (1976) G.Wolf, M.Zimmermann: The molar heat capacity of superconducting PdD x in the temperature
range from 2 to 12K. Phys. Status Solidi (a) 37, 485 (1976) O.J. Kleppa, C. Picard: H-H interaction in Pd-Ag alloys. Solid State Commun. 26, 421 (1978) R.J.Miller, T.O.Brun, C.B.Satterthwaite: Magnetic susceptibility of Pd H and Pd-D at
temperatures between 6 and 150 K. To be published M.Horobiowski, T.Skoskiewicz, E.Trojnar: Magnetization of the superconducting PdH. Phys.
Status Solidi (b) 79, K 147 (1977)
Author Index
Page numbers for this volume are indicated by italics. All other page numbers refer to Hydrogen in Metals I: Basic Properties, Topics in Applied Physics, Vol. 28, ed. by G. Alefeld, J. V/51kl (Springer, Berlin, Heidelberg, New York 1978)
274,276,277,285,286,289, Asch, L. 142, 159, 162 Abe, F. 334 298-300, 317,324 Ashby, E.C. 221 Abe, K. 289,297 Alekseevskii, N.E. 253 Ashcroft, N.W. 243 Abe, Y. 119, 120, 122,21 25, Alers, G.A. 93 Asher, R.C. 285,301
38, 39 Aleshin, V.G. 136 Aston, J.G. 321, 82, 84, 114- Abeledo, C.R. i48, 153, 164 Alexander, D.G. 55, 57, 58 117, 185 Abeles, T.P. 160, 164 Alexander, W.B. 282 Atkinson, G.A. 213 Aben, P.C. 69, 70, 85 Alikin, V.P. 326, 328 Au, J.J. 306, 307, 405, 323 Ableiter, M. 143, 149, 154, Allard, K. 120 Auer, W. 134-137, 139
155, 164,32 Allnatt, A.R. 274 Auluck, S. 253 Abragam, A. 232, 243, 244, Altenkirch, E. 3 Averbach, B.L. 109
262, 362-364 Amagat, E.H. 158, 159 Azou, P. 326-328
Abrahams, S.C. 217 Amano, M. 32, 43, 47, 51 Abramowitz, M. 203 Amato. I. 66 Abrikosov, A.A. 243 Amiot, P. 326, 328 Bacon. D.J. 311, 319 Achard, J.C. 236 Anderson, C.D. 349 Baker, B.S. 230 Achter, M.R. 58 Anderson, J.L. 222 Baker, C. 331,108, 109, 117, Acrivos, J.V. 247, 269 Anderson, J.R. 122, 123 320,321 Adda, Y. 274, 276, 278~80 Anderson, K.D. 22 Baldwin, T.O. 58 Adler, E. 312 Andreev, A.F. 385 Balzarotti, F. 108, 265 Afanasev, A.M. 144 Andresen, A.F. 223 Bangert, L. 301 Aharoni, J. 169, 171 Andrew, K.F. 214 Baranowski, B. 3,71,72, 108, Ahktar, A. 39I, 392, 406 Andrews, D.H.. 246 111,112, 124,201,326,328, Albert, Ph. 57 Andrievskii, R.A. 170 2, 78,90, 157, 158, 160-162, Albrecht, G. 124 Animalu, A.O.E. 79 164,167,169,172-181, 183, Albrecht, W.M. 40, 66, 329 Ansell, G.S. 325 185, 187-192, 194-197,249, Aldag, A.W. 85-87 Antonangeli, F. 108, 136, 251-254 Alder, B.J. 157 150, 157,265 Bardeen, J. 243 Alefeld, B. 58, 81,208, 212, Antonini, M. 62, 97, I8, 35 Barn, W.T. 57
213,222,223,267,273,274, Antonov, W.E. 174,177,178, Barnes, R.G. 235-239, 241, 279-283, 286, 329, 330, 193 242, 405 337, 341, 27,32,300 Antonova, M.M. 12t-123 Barnier, Y. 391
Alefeld, G. 1-3, 5, 6, 10, 24, Argent, B.B. 127 Barrer, R.M. 325, 326, 328, 32, 33, 40, 43-45, 53, 62, 63, Arons, R.R. 216, 236, 237, 142 65-70, 79-85, 89, 91-94, 239, 241,242, 247, 248, 259, Barrett, W.T. 110 96, 98, 108, 111, 134, 135, 335, 337, 341, 21, 22, 24, Barron, R. 202 145, 157, 159, 169, 199, 201, 30, 32, 40 Barthel, J. 58 209, 210, 212, 213, 220-222, Aronson, S. 119, 121, 123,32, Barton, W.A. 246 233, 252, 254, 256, 257, 279, 217 Bartram, S. 229 280,284,291,300,321-327, Artmann, D. 145 Baryshevskii, V.G. 406 329-341,343, 388,405,406, Asano, H. 68, 69, 81, 83, 84, Bastien, P. 326, 328 1~,9,11,13-15,26,32-34, 119, 120, 122, 19-26, 35, Batha, H.D. 215 41, 57, 63, 65, 66, 73, 99, 38-41 Batterman, B.W. 19, 21, 22, 148-15l, 237, 259, 260, 265, Ascarelli, P. 265 52-54
334 Author Index
Bauer, G. 2, 44, 45, 60, 80-82, 330, 32, 34, 311, 319
Bauer, H.C. 2, 45, 323, 334, 335-337, 339, 341,405, 406, 66
Bauer, H.J. 70, 187, 192 Bauer, R. 215 Baum, H. 124 Bauminger, E.R. 138, 143,
145, 160, 161,164 Bausch, R. 2, 13, 18, 19, 21,
22, 31, 42, 64, 66, 201,324, 13 I6, 28, 32-34, 43, 47, 52, 67, 276, 277
Beaudry, B.J. 70 Beaufrere, A.H. 201, 233 Beck, P.A. I29 Beck, R.L. 220, 227, 229 Beck, W. 326 328 Becker, J. 256,257 Beckman, C.A. 112,172,208,
223 Beg, M.M. 277 Begeal, D.R. 376,377 Belash, I.T. 174, 177-179,
i93 Bell, N.A. 217 Belyakov, Yu.I. 326, 327 Bemlyanov, M.G. 300 Bemski, G. 131, 148, 164 Bennemann, K.H. 252, 265 Bennett, L.H. 143, 149, 155,
164 Benson, J.E. 134 Bergmann, G. 244 Bergsma, J. 81, 86, 88, 277,
325, 94 Berkooz, O. 145 Berlincourt, T.G. 170, 35 Bernas, H. 248, 250, 269 Berninger, G. 70 Bernstein, I.M. 307, 315
317, 319 Berre, B. 43, 45, 63, 65-69,
91, 93, 201 Berry, B.S. 54 Berry, D.S. 14 Berthel, K.H. 58 Beshers, D.N. 321 Beske, H. 56 Bester, H. 342, 343 Bethe, E. 99, 103 Bevk, J. 110, 111, 259, 260 Beyl3, M. 58 Bhardwaj, B.D. 246
Bianconi, A. 108, 136, 150, 157, 265
Bickel, P.W. 170,35 Biegafiski, Z. 142, 160, 179 Bieman, L.H. 380, 381 Biggs, H.F. 107, 169, 171 Bilby, B.A. 311 Bilz, H. 79,81-83,94 Birchall, J.H.L. 279, 329,
330, 335 Birkholz, U. 208 Birnbaum, H.K. 209, 213,
281,306, 307, 322, 329-331, 339, 342, 380, 381,405, 406, 47, 51, 108, 109, 117, 286, 317, 320-322, 324, 325
Birr, M. 267 Bitter, F. 16 Bittner, H. 223, 247 Bixon, M. 161, 162, 164 Black, J.F. 97 Blackledge, J.P, 101, 102,
106, 113, 118, 127, 136, 137, 147, 173, 1, 81, 84, 207, 209, 212, 216, 217, 220, 224, 229, 238, 285,286, 293,298, 300
Bl~isius, A. 155, 164 Blaesser, G. 79, 204, 216, 271,
280 Blank, G. 57 Blank, Z. 237 Bleaney, B. 186 Bloch, F. 227 Bloembergen, N. 244, 364 Blohmholdt, G. 139, 140,
148 Bloom, J.W. 235,236 BRithner, K. 189, 261, 262 Blume, M. 144 Boccara, N. 26, 39 Bochefiska, K. 160, 173, 174,
176, 177, 179, 181, 187, 194, 196
Bockris, J.O'M. 325 328 B/Smmel, H.E. 159, 238, 331 Boes, N. 200, 325, 329-333,
340, 55, 61, 62, 79, 140, 142-150
Bohmholdt, G. 213,221,256, 325, 340, 293
Bohn, H.G. 236, 237, 239, 241,242, 247, 248,257, 259, 279, 335, 337, 341, 21, 22, 24, 30, 32, 40
Bohnhammel, K. 259, 260
Boiko, E.B. 170 Bojarski, K. 177-179, 181 Bokros, J.C. 289, 297 Bolef, D.I. 41,238 Bonnemay, M. 236 Bonnet, J.E. 70 Booker, R. 324,325 Borg, R.J. 213, 21%222, 304,
327, 338-340, 342, 376-378 Borghini, M 378, 380-382,
385,406 Borgucci, M.V. 290, 295 Bos, W.G. 160, 164, 170, 171 Boser, O. 391, 214, 237 Bosvieux, C. 282,295 Botter, F. 92, 97 Bottinger, J. 326,327 Boudart, M. 134 Boullough, R. 6 Boureau, G. 306 Bowles, J.S. 54 Bowman, A.L. 222 Bowman, R.C. 231-233 Boyer, L.L. 405 Bragg, W.L. 99 Brand, K. 322, 330, 331, 334 Brauer, G. 66, 15, 58, 65 Braun, C. 201 Breger, V. 325 Brendel, G.J. 221 Bressers, J. 53,55, 58 Breuer, N. 6 Brewer, J.H, 358, 386 392,
406 Brice, D.K. 406 Bridgman, P.W. 158, 159,
161 Brill, P. 149, 153, 154, 133 Briscoe, C.V. 85, 261, 262 Brockhouse, B.N. 86, 89 Brodowsky, H. 3, 172, 2, 73,
75-77, 8941, 93, 96, 100, lO1, 105-Ili , 114-123, 125-129, 132, 146, 215
Brodsky, M.B. 182 Brono~l, G. 236 Brooker, H.R. 237-239,241,
242 Brower, F.M. 220 Brown, C.R. 115 Brown, J.g. 265 Brown, W.F., Jr. 368 Bruksch, W.F. 246 Brun, T.O. 268
Author Index 335
Bruning, H.C.A.M. 182, 185, 187, 211, 222
Bryan, W.L. 326, 328 Brytov, I.A. 121-123 Buchanan, D.N.E. 131, 143,
147-149, 152, 155, 164, 192 Bucher, E. 125 Buchholz, J. 10, 63, 92, 201 Buchner, H. 233,234 Buchold, H. 79, 213, 331,
332, 338, 340, 134, 145, 148-150
Buck, H. 2, 5, 24 Buck, O. 64, 66, 30, 33 Buckel, W. 89, 90, 188, 247,
249-252 Bucur, R.V. 137 Budin, C. 310 Bujnowski, W. 108, 111, 90,
161, 162,164, 174, 177, 187, 188, 194, 249, 251, 252
Burattini, E. 108, 136, 150, 157
Burch, R. 6,62, 101 Burger, J. M. 1, 230 Burger, J.P. 129, 251, 253,
264, 266 Burgers, W.G. 69, 70 Burkhardt, T.W. 29, 39, 48,
276 Burton, H.H. 326, 328, 343 Buschow, K.H.J. 155, 160,
164, 188-190, 209, 211,220, 222, 223,229
Butera, R. 35 Butrymowicz, D.B. 376 Butterworth, J. 103 Butz, T. 141 Byer, N.E. 209
Cable, J.W. 190 Cahn, J.W. 2, 12, 15, 34, 39,
276 Callaway, J. 102, 105 Camani, M. 406 Cambini, M. 21, 24, 54 Camini, M. 376, 378-381,
384, 386 391 Cannelli, G. 331,325 Cantelli, R. 291, 329, 330-
333, 325 Carl, A. 11, 20-22, 24, 35-43,
53, 61 Carlile, C.J. 325, 150 Carlow, J.S. 1;48, 153, 154, 164
Carlson, O.N. 55, 57, 58, 287, 291
Carmichael, D.C. 326,328 Carr, H.Y. 253 Carson, A.W. 183 Carstanjen, H.D. 62, 63, 97,
300, I5, 18, 35, 66, 73, 326 Carstens, D.H.W. 215 Cashion, J.D. 142, 159, 160,
164 Cashion, J.K. 79, 106, 108,
109, 135, 136, 150, 157,261, 265
Caskey, G.R., Jr. 327, 310 Caspers, L.M. 285 Cassidy, M.P. 54 Caton, R.H. 257, 267 Caudron, R. 114, 118, 119,
18, 35 Cerm~ik, J. 326, 327 Chadwick, A.V. 274 Chain, E.E. 146, 164 Chandler, W.T. 40, 41, 66,
15, 31, 55 Chandra, D. 34 Chang, F.C. 218 Chang, H.Y. 31, 38, 39 Charnetskiy, V.G. 287, 292 Chaumont, J. 248, 250, 269 Cheetham, A.K. 90 Chekin, V.V. 152, 164 Chen, C.G. 213,32I Chen, J. 238 Ch6ne, J. 326, 328 Chernoplekov, N.A. 25, 40,
62, 80-82, 97, 300, 337, 15- 20
Chertkov, A.A. 25, 40, 62, 8~82, 97, 119, 122, 300, 337, 15~1, 23-25, 185
Chervyakov, A.Yu. 119, i22, 20, 21, 23-25
Chiba, T. 54 Childs, B.G. 170 Chiu, J. C.H. 265 Choi, J.Y. 326, 328 Chou, Y.T. 316 Chowdhury, M.R. 81, 86, 88,
89, 91, 261 Christian, R.H. 157 Chudinov, M.G. 136 Chudley, C.T. 223, 249, 250,
269 Chui, S.T. 79 Cinader, G. 182
Clarebrough, L.M. 308 Clark, R.G. 57 Clasen, H. 221 Clewly, J.D. 406, 79, 81, 92,
312, 313 Clinton, J. 223,247, 269 Clogston, A.M. 155 Clune, L.G. 78 Coates, G.E. 217 Cochardt, A.W. 3I i Coeha, A. 287,293 Cohen, M. 109 Cohen, M.H. 234 Cohen, R.L. 160, 164 Coldrick, S. 213 Coldwell, D.M. 306 Coles, B.R. llO Collings, E.W. 119 Combette, P. 327 Compton, V.B. 191,246,257 Condon, J.B. 207, 214 Conrad, H. 2, 44, 45, 80-82,
330, 32, 34, 86, 87 Conversi, M. 349 Coogan, C.K. 230, 231, 240 Cook, A.J. 15 Cook, H.E. 6 Coon, V.T. 193 Cooper, B.R. 186 Cooper, L.N. 243 Cooper, M. 269 Cordey-Hayes, M. 126 Corenzwit, E. 155, 193 Cornell, D.A. 247, 255, 256,
259 Costa, P. 67, 114, 118, 119,
18, 35 Cottingham, J.G. 1, 237 Cotton, F.A. 206, 229 Cottrell, A.H. 311, 316 Cotts, R.M. 227, 231, 240-
242, 244, 247, 252, 254-256, 259, 276, 277, 335, 1I, 30, 32, 139
Couch, J.G. 78 Courdan, R. 67 Courtney, M.L. 222 Craig, R.S. 67, 112, 179, 183-
185, 193, 35, 117, 172, 208, 223,229
Crangle, J. 152 Crank, J. 57 Creten, R. 55, 58 Crowe, K.M. 358, 390 Cummings, D.L. 235
336 Author Index
Curran, T. 79, 81,92 Cyklis, D.S. 159 Czarnota, I. 173
Da Silva, J.R.G. 314, 315 Dander, W. 304 Danon, J. 131,148, 151,152,
164 Dantzer, P. 62, 286, 293,306 Danz, W. 90 D'Arsonval, J.A. 7 Das, A.K. 282, 283,290 Das, Sh.G. 406 DaSilva, X.A. 131, 148, 164 Dattagupta, S. 142, 159 Daunt, J.G. 119 Davidov, D. 143, 161, 164 Davis, P.P. 247, 252, 255,
256, 276, 277, 139 Davis, W.D. 325 Dawber, P.G. 75 Daynes, H. 142 De Fontaine, D. 6 De Graaf, A.M. 131, 148,
164 De Graaf, L.A. 81, 83, 87,
273,276--278, 281,285, 325, 331,332, 335
De Graaf, W. I59, 169 De Groot, S.R. 274,276,279,
280 De Pasquali, G. 147, 148, 154 De Ribaupierre, Y. 5, 24, 69,
70, 110 De Vries, G. 216 Deckers, H. 79, 89,90 Dederichs, P.H. 15, 16, 58 Deenadas, C. 179, 184 Degani, G. 182 Degreve, F. 56 Detain, V.B. 325, 340, 287 Dennison, W.F. 289, 297 Dergach~v, Yu.M. 221 Derrick, R.G. 327, 310 DeSorbo, W. 55 Dettmann, F. 189, 261, 262 Deutscher, G. 247, 269 Devanathan, M.A.V. 325,
326, 328, 142-146 Devine, R.A.B. 265 Deviot, B. 327 Dexter, A.H. 327 Dharia, D. 235,236 D'Heurle, F.M. 274, 294 Diederichs, H. 145, 150
Dieterich, W. 223 Dietrich, M. 89,90,257-259,
267, 268 Dietze, H.D. 299 Digges, T.G., Jr. 58 Dijkstra, L.J. 320 Dillard, J.-L. 326, 328, 329,
387, 388 Dilthey, D.F. 227, 229 Dimmock, J.O. 107, 110,
111,136 DiSalvo, F.J. 247,269 Dobson, P.S. 308 Dodge, B.F. 326,328 Doilins, C. 320 Domke, E. 326, 328, 329 Donath, W.E. 186 Donovan, J.A. 327, 317 Dorenburg, K. 380-382, 406 Downs, W.R. 89 Doyle, M.V. 321,319 Doyle, T.B. 251, 253 Dr~iger, G. 124 Drain, L.E. 251 Dresler, W. 326 328, 342,
I08, 109 Drexel, W. 81, 201,276, 286,
325, 89, 92, I09, 149, 150, 264
Drickamer, H.G. 147, 148, 154
Droege, J.W. 289, 297, 299 Drowart, A. 56 Drowart, J. 56 Drulis, M. 142, 160 Ducastelle, F. 67, 114, 118,
119, 18, 35 Duclos, M. 273, 289, 297 Duffer, P. 246 Dufresne, J.F. 306, 307, 388 Dugdale, J.S. 133 Duke, C.B. 405 Dumoulin, L. 248 Duncan, R.A. 391, 392, 406 Dunlap, B.D. 137, 142, 143,
159, 160, 164 Dunlop, J.D. 236 Dwight, A.E. 137, 142, 143,
159, 160, 164 Dye, D. 110 Dymova, T.N. 215, 22I Dynes, R.C. 261,262
Earl, M.M. 236 Early, S. 247, 269
Eastman, D.E. 79, 106, 108, 109, 116, 135, 136, 150,
157, 261, 405, 90, 133, 265 Eastman, J.C. 217 Ebisuzaki, Y. 220, 221, 304,
327 Ecklund, E. 235 Economou, E,N. 405 Edwards, A.G. 327 Edwards, R.K. 40, 57, 62,
209, 285, 286, 293, 298 Egelstaff, P. 76, 77 Eggs, J. 132 Ehrenreich, H. 108, 110, 127 Eibler, R. 103 Eichenauer, W. 304, 307,
325 328, 338, 339, 378, 380, 287, 288, 293
Eichler, A. 85, 88, 188, 252, 261-263
Einziger, R.E. 287, 288, 29I E1-Hanany, U. 182 Elleman, D.D. 263 Ellemann, T.S. 34 Elliott, R.J. 75, 223, 249, 250,
269 Ellis, D.E. 141 Ells, C.E. 310 EIMaslout, A. 146 Elssner, G. 55 Engelhard, J. 212, 331, 341 Engelsberg, M. 231 l~ntin, I.R. 119, 122, 21, 23
26, I85 Erckmann, V. 288, 289,291-
295 Erdmann-Jesnitzer, F. 326,
328 Ertl, G. 86, 87 Eshelby, J.D. 6, 7, 16, 140 Euringer, G. 327 Evans, G.M. 326, 228 Evans, M.J.B. 168 Evans, W. 310 Everett, D.H. 168, 207 Ewe, H.H. 1,236 Eyring, H. 218
Faber, J. 283, 117 Faber, K. 212, 341, 32, 57 Falicov, L.M. 390 Fal'ko, I.I. 331,332 Failer, H.G. 108, 109 Farr, J.D. 215, 217 Farr, J.P.G. 111
Author Index 337
Farell, H.H. 57 Farrell, J.J. 184--186 Fast, J.D. 213, 229, 306, 320 Faulkner, J.S. 108, i10, 111,
136, 150, 157,260 Faust, J.P. 215 Favreau, R.L. 340 Fedders, P.A. 238 Fedorova, A.J. 159 Fehmer. D. 137. 139 Feinberg, G. 350,352 Feiock, F.D. 141 Feit, M.D. 282 Felner, I. 143, 161, 164 Fender, B.E.F. 90, 179, 180 Fenzl, H.J. 31-33, 49, 58~60 Ferguson, G.A. 87, 276, 325,
117, 185 Fermi, E. 357 Figueroa, S. 248 Fiks, V.B. 281-284, 295 Filipek, S. 157, 175, 176, 181,
182, 187, 190-192, 194 Finemann, M.A. 110 Fiory, A.T. 380, 381, 385,
392, 393, 406 Fischer, D. 115 Fischer, K. 58 Fischer, W. 327 Fisher, E.S. 63, 66, 67, 91 Fisher, J.C. 108, 109 Fitzwilliam, J. 170 Flanagan, T.B. 1, 3, 69 71,
112, 201, 325, 406, 65, 73, 77-79, 81, 82, 84, 88, 92, 98, 101, 120, 136, 137, 142, 145, 148, 172, 181, 194, 210, 286, 287, 290, 312, 313
Fleming, D.G. 386 389, 391, 392, 406
Flocken, J.W. 16 Flotow, H.E. 66, 81, 83, 85
88, 93-95, 110, 271 273, 277-279, 281, 285, 331- 335, 94, 117, 185, 260-264, 266, 269
Flynn, C.P. 209-212, 214- 216, 281,291,376, 380, 381, 294, 299
Fober, J. 185 Fogle, C.E. 215 Fontell, N. 110 Forman, R.E. 216 Forster, A. 162
Foster, P.K. 307,308 Fowler, R. 5 Foy, M.L. 386, 387, 390 Fradin, F.Y. 146, 164 Francis, N.B. 62 Frank, R.C. 326, 328 Freeman, A.J. 107, 110, 111,
136, 141,405 Freilich, A. 173,174,181,187 Freudenberg, U. 2, 65, 333,
339, 405, 406 Freund, A. 60 Friedel, J. 199, 295, 108, 130,
131, 282, 295 Friedrich, K. 57 Friedt, J.M. 144, 152, 164 Frieske, H. 79-82, 84, 85,
107, 108, 128, 129 Fritz, J.J. 321 Frohberg, M.G. 342, 108,
109, 282 Fromm, E. 55-58, 63, 306 Frumkin, A.N. 159, 167 Fujii, S. 406 Fujita, F.E. 148, 155, 164,
327 Fukai, Y. 121-123, 157,260-
263, 337, 341, 22, 38, 39 Fulde, P. 223 Fullenwider, M. 325, 327,
328 Furdyna, A.M. 107, 110,
111, 136
Gal, J. 161,162, 164 Galland, J. 326, 328 Ganguly, B.N. 79, 88, 261,
264-266 Gans, E. 97, 98 Gardner, W.E. 170 Garg, S.C. 203 Garland, J.W. 252, 265 Garner, D.M. 386-389 Garno, J.P. 261, 262 Gaspari, G.D. 104, 105 Gatos, H.C. 246 Gatta, A. 177 Gauster, W.B. 380, 385, 406 Gavrilov, S.D. 159 Geballe, T.H. 246, 247, 257,
269 Gebel, R. 58 Gebhardt, E. 55, 57, 63, 306 Gegg, C.C. 326, 328, 343
Gehm, G. 70 Gelatt, C.D.,Jr. 108,110,127 Gel'd, P.V. 325, 326, 328,
340, 287 Geller, S. 2 Geller, W. 326, 328, 343 Gensamer, M. 306 Genshaw, M.A. 325, 327,
328 Gerl, M. 282-284, 290, 294 Gerstenberg, D. 127, 129,
130, 256 Gesi, K. 114 Gevers, R. 21, 24,54 Gey, W. 257, 258 Gibala, R. 306, 317-320 Gibb, T.C. 132, 138, 139,
141,142, 146 Gibb, T.R.P. 68,69,295,2•,
26, 40, 195, 206, 211, 227, 229
Gibmeyer, H. 96 Gibson, M. 254 Gidaspow, D. 235, 236 Gierisch, W. 139, 142, 143 Gilberg, E. 108, 121,123, 26l Gilbon, D. 248 Gileadi, E. 325,201 Gill, D. 253 Gillespie, D.J. 108, 111,247,
259, 260 Gillespie, L.J. 89 Ginsberg, A.P. 217 Giorgi, A.E. 259 Gissler, W. 62, 79 81, 84,
223, 250, 267, 271,273 275, 277, 279, 280, 282-284, 300, 329, 330, 335
Gladisch, M. 380-382, 406 Glinchuk, M.D. 282 Glinka, C.J. 85, 87, 93, 97,
98, 261 Glover, R.E. 250,261 Glyde, H.R. - 219 Goedkoop, LA. 81, 86, 88,
277, 325, 94 G61tz, G. 45 G/5ltzer, H. 215 Goldanskii, V.I. 132, 138,
139, 141,142, 146 Goldberg, H.A. 21 Goldman, M. 233 Gol'tsov, V.A. 325, 287,310
338 Author Index
Gomersall, I.R. 266 Gonser, U. 132, 138, 139,
141-143, 146, 149, 154, 155, 164, 32
Gonzalez, O.D. 287-289, 292, 293,298, 299, 316
Goode, W.D. 40, 66, 329 Goodier, J.N. 21 Gordon, J.E. 267 Gorelkin, V.N. 373 Goretzki, H. 114, 115, 119,
174 Gorham-Bergeron, E. 216,
217 Gorobchenko, V.D. 144 Gorski, W. 99 Gorsky, W.S. 62, 300 Goto, S. 289, 298 Gottesfeld, S. 20I Goudy, A. 208, 223 Govindan Namboodhiri, T. K.
326, 328 Grabke, H.J. 134-137, 139 Graefe, A.P. 217,218 Graf, H. 386-389, 391, 392 Graham, L.D. 260 Graham, T. 1, 1, 73, 78, 204 Grebinnik, V.G. 373-378,
385 Grechanaya, N.A. 221 Green, L. 204 Greenwood, N.N. 132, 138,
139, 141,142, 146 Griessen, R. 110 Grimes, H.H. 327 Groh, P. 306, 307, 388 Grone, A.R. 281, 282, 295 Grossbeck, M,L. 47, 51 Gruen, D.M. 182, 1, 7, 11,
237 Grfinwald, W. 55, 57, 58 Grushina, V.V. 227 Gschneider, K.A, Jr. 170 Gualtieri, D.M. 188, 189,
193, 213,246 Guberman, H.D. 58 Gu6nault, A.M. 133 Gtintzler, G. 58 Guggenheim, E.A. 5, 99,
102, 103, llO Guggisberg, D.G. 289, 297 Gull, J.M. 337, 341 Guinan, M. 213, 219-222,
300, 327, 338 340, 342, 376-378
Gulbransen, E.A. 325, 208, 214, 227, 287
Gupta, M. 405 Gurevich, I.I. 213, 363,
374 378, 385-392 Gurskaya, A.V, 25, 40, 62,
97, 300, 337, 15-20 Gutermuth, M.F. 7 Guthrie, G.L. 246 Gutowsky, H.S. 230, 231,
240 Gygax, F.N. 358, 376,
378-381,384, 386 391,406 Gyorffy, B.L. 104, 105, 266
Haase, R. 274, 276, 280
I-Iadari, U. 182 Hadari, Z. 161, 162, 164 Hael3ner, F. 55, 57, 58 Hafner, J. 79 Hagemark, K. 126 Hahn, R. 301 Halder, N. 162 Hall, C.K. 30 HallW. K. 207 Hamagaki, H. 390 Hanada, R. 212, 321, 331,
334, 341,326 Hanawalt, J.D. 69,70 Hanke, W. 79 Hansen, W.W. 227 Hanson, M. 124, 125 Hardcastle, K.I. 68, 69, 21,
26, 40, 2II, 217, 221 Hardie, D. 43 Hardy, G.F. 259 Hardy, J.R. 6, 16 Harkins, C.G. 13, 245 Harling, O.K. 78 Harmon, B.N. 269 Harper, J.M.E. 249, 251 Harris, I.R. 111,126 Hartmann, O. 365, 366, 378,
380-382, 385, 406 Hartmann-Boutron, F. 142,
144, 145, 159 Haselden, G.G. 202 Hashimoto, O. 390, 406 Hashimoto, T. 337 Hashizume, H. 320 Hatcher, A.P. 289, 297 Hauck, J. 134, 158, 15-17, 34 Hautecler, S. 79, 89, 90, 97,
98
Hayano, R.S. 305, 386-389, 391, 392, 406
Hayashi, E. 125 Hayes, H.F. 211,227 Hayward, D.O. 337, 341 Heckman, R.C. 175 177,
246 Heffner, R,H. 380, 385, 406 Hehenkamp, T. 274,283,300 Heibel, R. 32 Heidemann, Albert 3, 145,
155-159, 164, 267,271,275, 322, 324, 331,332
Heidemann, Anton 212,213, 222, 267, 280, 281,286, 329, 330, 341,300
Helm, A. 83, 224, 278, 279, 283
Helm, G. 249 Heiman, N. 386, 387, 390 Heiniger, F. 125 Heintze, V. 405 Heller, G. 287,293 Heller, R. 333, 29, 38, 289,
290, 295, 298 Heller, W.R. 216, 306 Hellwege, K.-H. 368 Hemminger, W. 57 Henry, W.E. 182 Herber, R.H. 132, 138, 139,
141,142, 146 Herbst, G. 305 Herlach, D. 380-382, 406 Herman, F. 106 Herman, R. 66 Hermant, M.E. 306 H6rold, A. 286, 287, 290-293 Hertel, P. 79, 85,265 Hess, J. 160, 164 Heumann, T. 109 Heumann, Th. 326, 328,329,
343 Heying, T.L. 215 Hieber, H, 326, 328 Hill, M.L. 326-328 Hill, T.L. 99, 102 Hillert, M. 34, 39 Hilliard, J.E. 34, 39 Hillmann, H. 11 Hilzinger, H.R. 293,299, 370 Himrnler, W. 121-123 Hirabayashi, M. 68, 69, 81,
83, 84, 119, 120, 122, 19-26, 35, 38-41
Hiraga, K. 35
AuthorIndex 339
Hirota, T. 363, 379 Hirth, J.P. 311,317 Ho, J.C. 119 Ho, N.S. 115 Hoare, F.E. IO1, 129 H6rz, G. 3t, 55,56 Hoffman, K.C. 203,214, 230 Hofmann, S. 55, 57, 58 Hofmann, W. 392 Hohler, B. 315 Hold, B.D. 57 Holden, T.M. 152 Holleck, G. 213, 221, 256,
325, 139, 148 Holley, C.E. 175 Hollingsworth, C.A. 178 Holstein, T. 198, 204, 207,
208, 210, 211,405 Holtz, A. 237 Honigmann, M. 7 Hopkins° B.E. 15 Horn, F,H. 246 Hornaday, J,R. 326, 328 Horner, H. 2, 7, 9, 10, 13, 18,
19, 21-23, 25, 27, 29, 30, 39-42~ 200, 205, 206, 209, 324, 26, 276, 277, 31l, 319
Hovi, V. 110 Huang, C.Y. 380, 385, 406 Huber, B. 405, I39, 145, 149 Hudson, J.B. 325 Hull, G.W. 247,269 Hulm, J.K. 259 Humble, P. 308 Hunt, D.G. 87, 89, 90, 94 Huntington, H.B. 274,
281-283,287,288,291,295, 296
Hurd, C.M. 293,296 Husemann, H. 172, lOl, 105,
109, 118-t22, 125-129 Hutson, R.L. 380, 385, 406 Hwang, Y.S. 405 Hyv6nem L. I10
Iannarella, L. 145, 151, 152, 164
Igalson, J. 189, 261, 262 Indrea, E. 137 lngalls, R. 147, 148, 154 Ioffe, R.B. 170 Ionov, N.I. 326, 327 Isaacs, H.S. 57 lschino, Y. 19,20,35 lshikawa, M. I89, 247, 269
lshikawa, Y. 386, 387-389 Ishino, S, 289,291 Isler, R.S. 1,230,233 Ivanter, I.G. 373,374 Ivashina, Yu.K. 287, 292 Iwata, K. 319
Jaccarino, ¥. 258 Jack, K.H. 320 Jacobi, N. 117 Jacobs, J.K. 110, t52, 115,
185 Jakob, D. 57 Jamieson, H.C. 107, 110,
111,169, 171-173,251,256, 266
Janot, Ch. 139, 147, 148, 164 Janssen, H.-K. 34, 36, 37,
199, 324 Jay, B. 223, 282, 283 Jech, A.E. 148, 153, 164 Jegorov, A.N. 159 Jehn, H. 57 Jena, P. 378, 387, 390, 406 Jepsen, O. 116, 119 Jeulink, J. 285 Jewett, D.N. 325 Johnson, E.W. 326-328 Johnson, H.H. 326, 328, 406,
309, 310, 313, 316, 317 Johnson, J.R. 226, 227, 233 Johnson, R.F~ 390 Johnson, W.R. 141 Johnston, I.A. 308 Jones, D.M. 320 Jones, D.W. 227 Jones, H. 2, 107, 169, 171,
127 Jones, W.M. 94
Joppien, K.-D. 326, 328 Jordan, R.G. 274, 285, 300 Jorgensen, J.D. 268 Jost, W. 221,325, 340, 287 Jtirgens, H. 287,293 Jung, P. 363 Jupille, J, 56 Jurisch, M. 58 Just, W. 60 Justi, E.W. I, 236
Kachmar, B.F. 291 Kagan, G.Y. 204, 208,216,
217, 223,325, 340, 287
Kaindl, G. 3, 138, 145, 149, 155-159, 164, 267, 271,275, 322, 324, 331, 332
Kalberlah, A.W. 236 Kalvius, G.M. 138, 139, 142,
143, 145, 146, 160, 162, 164 Kamada, K. 58 Kammer, E.W. 185 Kankeleit, E. 138, 144 Kanzaki, H. 10, 54, 201 Kappus, W. 39 Karger, M. 144-146,
150-152, 164 Karlsson, E. 378,380-382,
385, 406 Karnus, A.I. 331,332, 151 Kass, W.J. 220,221,304, 327 Kasuya, T. 169, 175 Katz, L. 213, 219-222, 304,
327, 338 340, 342, 376-378 Katz, O.M. 325, 208, 287 Kaufman, A. 170 Kaufmann, B. 77 Kaufmann, E.N. 141 Kawakami, M. 363, 379 Kay, M.I. 217, 220 Kazama, S. 121-123, 157,
260-263, 337, 341, 22, 38, 39
Kehl, G.L. 342 Kehr, K.W. 3, 158, 159, 197,
207, 213, 216, 223, 224, 267, 268, 273-275, 282-286, 343,406, 11
Keiser, J. 324, 325 Kester, F. 235 Khachaturyan, A.G. 6, 18,
34, 66 Khadzhay, G.Ya. 331, 332,
287, 292 Khan, A.S. 405 Khan, H.R. 124, 125, 170 Khodosov, E.F. 247, 261 Khotkevich, V.I. 331,332,
151,287, 292 Kies, A. 139, 147, 148, 164 Kikuta, Y. 319 KimbaI1, C.W. 146, 148, 152,
153, 164 Kimura, H. 212,334 Kirchheim, H. 57 Kirchheim, R. 55, 58 Kirschfeld, L. 229 Kissinger, H.E. 246
340 Author Index
Kistner, G. 279 Kitada, M. 289,297 Kitchens, T.A. 147, 152, 155 Kittel, C. 169, 175 Klatt, K.-H. 70, 213, 221,
325, 338, 340, 11, 55, 61, 149 Klein, B.M. 108, 111,405,
266 Klein, M.V. 309 Kleinberg, R. 217, 220 Kleppa, O.J. 62, 286, 293,
306 Kley, W. 75, 79-81, 84, 202,
204, 276, 279, 286, 322, 325, 329, 330, 334, 89, 92, 109, 149, 150, 264
Klimov, A.I. 385-387, 390-392
Klimov, A.N. 386 390 Klinger, M.J. 204, 208, 216,
217, 223 Knaak, J. 325, 287, 288, 293 Knapp, J.A. 405 Knauer, R.C. 146 Knight, W.D. 258 Knoedler, A. 124, 125, 170 Knorr, K. 179, 180 Knott, H.W. 119, 120, 122,
21, 23 25, 40 Knox, K. 217 Kobetz, P. 221 Kobo, R. 158 Koch, C.C. 55 Koch, W. 139, 142, 143 Kock, W. 109, 110 Koda, S. 289, 297 K/Sbler, U. 31,35,36 Koehler, J.S. 16 Koehler, W,C. 190 Koenemann, E. 7,9 K6nig, H.-J. 326,328 K/3nig, N. 308, 309, 311,326,
317, 324 K/Srding, A. 144 Koester, L. 76 K/Sster, W. 301 Koffler, S.A. 325 Kofstad, P. 35 Koi, T. 363, 379 Koiwa, M. 308 Kokkinidis, M. 331, 332,
341,405, 406 Kollmar, A. 81 83, 94, 269 Kolobova, K.M. 115, 116 Konashenok, K.I. 121-123
Konstantinova, A.J. 220 Korn, C. 255, 257, 259 Korringa, J. 258 Korst, W.L. 211,229 Koski, H. 110 Kossler, W.J. 380, 381,
385-387, 390, 392, 393, 406 Kost, M.E. 25, 40, 62, 97,
300, 337, 15-20 Kovacevic, S. 221 Kov~cs-Cset~nyi 406 Krainer, H. 326, 328 Kraus, T. 57 Krenke, M. 380-382 Kress, W. 81 83, 94 Kripyakevich, R.I. 287, 29I,
292 Krivoglaz, M.A. 2, 6, 12, 22,
77, 145, 146, 158 Kr6ger, D.M. 55 Kr6ner, E. 15, 293 Krogdahl, T. 234, 335 Kronmtiller, H. 3, 289 291,
293-295, 298, 299, 301, 304 311,315,326,370,391, 317, 324
Kriiger, F. 70 Kriiger, G.J. 252, 335 Krukowski, M. 71, 72, 124,
162, 175, 179, 180, 194 Krupka, M.C. 259 Kryukova, O.N. 220 Kuballa, M. 196 Kubicka, H. 85 Kubo, R. 239, 363, 364 Kubota, Y. 174, 176, 177, 180 Kudielka-Artner i27 Ktindig, W. 386-389, 391,
392 Kfinzig, H. 307, 326, 328 Kiissner, A. 78, 134, 140,142,
144, 146, 148, 215 Kufudakis, A. 326, 327 Kuipers, F.A. 161, 182, 185,
187, 208, 211, 222 Kuke, A. 301 Kulikov, N. 405 Kumar, P. 282 Kumnick, A.J. 326, 328,406,
309, 313,316 Kunze, J. 58 Kurmaev, E.Z. 121 123 Kuten, S.A. 406 Kuznietsov, V.V. 326, 328
Lacher, J.R. 1, 323, 65, 75, 101, 168, 285
LaConti, A.B. 201 L~isser, R. 269 L~iuger, K. 159, 238, 331 LaFleur, W.J. 246 Lakner, J.F. 222,223 Lalu, F. 248 Lam, D.J. 127 Lambrou, Ch. 129 Lamoise, A.M. 248, 250, 269 Lampert, G. 291 Landau, L.D. 2, 30, 352 Landauer, R. 282, 290, 295 Lang, E. 53 Lang, G. 341, 405, 406 Lange, K.W. 326, 327, 342,
343 Langer, J.S. 38, 39 Lankford, W.F. 380, 381,
385, 392, 393, 406 Larkin, C.F. 327 Larson, E.A. 214 Lassner, E. 57 Latta, E.E. 86, 87 Lattes, C.M.G. 349 Lau, K.F. 406 Lawson, A.C. 170 Lawson, A.W. I09 Lea, K.R. 137, 159 Leask, M.J.M, 137, 159 Lebsanft, E. 406 LeClaire, A.D. 219, 220 Lecocq, P. 35, 36,53 Lederman, L.M. 350, 352 Lee, R.W. 326. 328 Lee, T.D. 1,352, 99 Lehrfeld, D. 237 Leibfried, G. 6, 15 Leich, D.A. 65 Lengeler, B. 110, 65, 269, 309 Leon, M. 380, 385, 406 Lepski, D. 204 Levelt, J.M. 159~ I69 Leventhal, M. 380 Levine, P.L. 160, 191 Lewis, F.A. 101, 106, 111,
73, 77, 79, 10I, 118, 162, 168, I73, 181, 183, 185, 189-191, 194, 195, 229, 249, 253
Lewis, L.L. 57 Lewis, P.A. 1,230 Li, J.C.M. 311,316
Author Index 341
Libowitz, G.G. 90, 97, 98, 101, 102, 106, 113, 118, 127, 136, 137, 147, 173, 1,81,84, 206, 207, 209, 211,212, 216, 217, 220, 224, 227, 229, 237, 238, 285,286, 293, 298, 300
Lie, K.H.G. 16 Lieser, K.H. 327, 121, 122 Lifshitz, E.M. 30 Lifshitz, I.M. 385 Lilley, E.M. 157 Lindemaier, K. 56 Lindemuth, J. 380, 381 Linke, U. 29, 32, 43-47 Lipkin, H.J. 77 Lister, M.W. 110 Litterst, F.J. 139, 142, 143 Livingston, R.C. 81, 83, 278,
285, 331,332, 335 Lodge, K.W. 141 L6bI, G. 73 L6ser, W. 304, 327, 338, 339 Longworth, G. 153, 149, 154,
I3I Look, D.C. 243 Loopstra, B.A. 182, 187 Loos, W. 56, 70, 71 Lord, A.E.,Jr. 321 Lorentz, H.A. 368 Loretto, M.H. 308 Loser, W. 378, 380 Lottner, V. 81-83, 94, 224,
278, 279, 283, 269 Lounasmaa, O.V. 164 Louthan, M.R.,Jr. 327 Louverse, P. 159, I69 Lovesey, S. 267, 271,275 Low, G.G. 152 Lowe, I.J. 243 Lowndes, D.H. 110 Lozes, G. 327 Lucasson, A. 310 Lucasson, P. 310 Ludwig, P. 325, 77, 142, 144,
145, 207 L~itgemeier, H. 236,237,239,
241,242, 247, 248, 259, 335, 337, 341, 21, 22, 24, 30, 32, 4O
Lukas, H.L. 57 Lundin, C.E. 215, 218, 222,
226 Lyle, S.J. 160, 164 Lynch, F.E. 215,218,222,226
Lynch, J.F. 77, 78, 82, 84, 98, 136, 210, 312, 313
Lynn, K.G. 380, 381,406
Maas, H. 326, 328, 343 Mackliet, C.A. 108, 111,101,
114, 129, 247, 259, 260, 266 Mader, K.H. 174, 176-179,
186 Madhukar, A. 405 Maeland, A.J. 68-70, 97, 98,
2l, 23, 24, 38, 120, 195, 217, 223
Maestas, S. 142, 145, 148 Magee, C.B. 215, 218, 222 Magerl, A. 43, 45, 63, 65-69,
80, 8L 83, 91-94, 96, 98, 201,260
Mahnig, M 79, 108, II~112, 136, 148-150, 157, 164, 105, 128, 129, 133, 260
Mailfert, R. 264, 266 MMorov, V.N. 385-392 Mair, G. 26 Majchrzak, S. 71, 112, 201,
78, 162, 172 176, I79, 181, 185, 187, 189, 191, 194-196
Makarov, A. IlO Makrides, A.C. 325 Maksimov, E.G. 199 Malamud, M. 145 Maletta, H. 144 Malik, S.K. 190, 191, 193 MaIIett, M.W. 40, 66, 329,
227, 229 Manchester, F.D. 5, 24, 69,
70, I07, 110, 111, 152, 169, 171-173, 65, 99, 115, 185, 251, 256, 266
Mann, E. 367 Manning, J.R. 376 Mannsman, M. 175 Mansel, M. 406 Mansfield, P. 231,233 Manych, A.P. 373-378, 385 Mar6ch6, J.-F. 287, 290-293 Maria, H.J. 321 Marshak, R.E. 349 Marshall, R.P. 289, 297 Martel, P. 94, 95 Martinez, R. 306, 307 Marzouk, N. 183, 184 Maslennikova, W.A. 159 Mason, M. 279
Massalski, T.B. 110, 111, 259, 260
Masumara, R.A. 16 Matsumoto, M. 121-123,
157, 261 Matsumoto, T. 325 Mattas, R.F. 322,323 Mattheiss, L.F. 95, 106 Matthew, J.A.D. 206, 214,
294 Matthias, B.T. 155, t93,246,
257 Mattis, D. 186 Matusiewicz, G. 329,330,
339, 342, 324,325 Matzek, N.E. 220 May, B. 21 May, L. 132, 138, 139, 141,
142, 146 Mayer, S.F. 247, 269 Mayet, J. 221 Mayluchkov, O. 405 Mazur, P. 274, 276, 280 Mazzolai, F.M. 329-333,
325 McBeth, R.L. 1, 7, 237 McBreen, J. 326, 328 McCaffrey, J.W. 122, 123 McClaine, A.W. 203 McCoy, W.H. lIO McFall, W.D. 173, 18l, 185 McGhie, A.R. 405 McIntyre, P. 43 McKinley, T.D. 227 McLachlan, D.S. 251, 253,
264, 266 McLellan, R.B. 295, 306, 13,
117, 125, 245, 285, 293, 306, 307, 314,315
McMillan, W.L. 104, 105, 244, 261
McMullen, T. 366, 406 McNabb, A. 307,308 McQuillan, A.D. 112, 227 Meads, R.E. 148, 153, 154,
164 Mecea, V. 137 Mehlmann, R. 172, 101, 105,
119, 126-129 Meiboom, S. 253 Meier, P.F. 367, 378, 391,
392 Meijer, R.L. I, 233 Meijering, J.L. 320 Melchior, G. 56
342 Author Index
Mel'eshko, E.A. 213, 363, 374-378, 386 390
Melnichak, M.E. 62,286, 293
Melnick, L.M. 57 Mel'nikov, E.V. 385 Mendelsohn, M. 1, 7, 237 Merisov, B.A. 331, 332, I51,
287, 292 Merker, P. 112, I72 Merriam, M.F. 246 Mers, R.G. 217 Merten, U. 289.297 Meservey, R. 253 Messer, C.E. 217, 218, 220 Metz, H. 380-382, 406 Metzger, H. 41, 58, 59, 64 66,
276, 311 Meunier, F. 248, 250, 269 Meyer, K. 326, 137-139 Meyer, M. 152, 164 Meyerhoff, R,W. 58 Meyers, N.F. 110 Michel, J.M. 56 Michels, A. 159,169 Miedema, A.R. 209, 211,
220, 222, 223,229 Mikheeva, V,1. 220 Milau, J.S. 1,233,236 Miller, A.P. 86, 89 Miller, J.F. 257, 267, 268 Miller, R.J. 88, 90, 251, 264,
265 Mindyuk, A.K. 315 Minnerup, W. 88 Minnich, R.P. 380, 381, 385 Mintz, M.H. 161,162, 164 Miodownik, A.P. 306, 326,
328, 288, 318 Mishima, Y. 289,291 Mitacek, P. 114-I17 Mitchell, J.B. 30, 33, 34 Mituya, A. 196 Miura, S. 55 Miyazaki, N. 289, 291 Mizutani, T. 147, 148, 164 Mizutar~i,.U. 110, 111, 259,
260 M611er, H.S. 152 Moers, K. 218 Monachesi, P. 370 Montgomery, H. 10I~ 129,
133, 266, 267 Montroll, E,W. 79 Moody, D.E. 254
Moore, W.E. 80 Mori, N. 126 Morita, P. 185 Morkel, Ch. 209,405 Morosin, B. 70, 77, I l l , 266 Morozumi, S. 289, 297, 298 Morris, A.E. 326, 328 Moser, J. 145, 151, 152, 164 Moser, P. 290, 306, 307, 388 Mosher, D. 320 Moss, R.L. 107 Mostoller, M. 81,85 88,110,
94, 260, 262-264, 266 Mott, N.F. 2, 107, 169 171,
127 Motte, J.P. 146 Moyer, R.O. 217,220 Muddle, B.C. 54 Miill, P. 58 Mueller, F.M. 107, 110, 111,
136 Miiller, H. 18, 58, 65 Mueller, M.H. 119, 120, 122,
283, 21-25, 40, 117, 185 Mtiller, W. 162, 173 Mueller, W.M. 101,102, 106,
113, 118, 127, 136, 137, 147, 295, I, 81, 84, 207, 209, 212, 216, 217, 220, 224, 229, 238, 285, 286, 293, 298, 300
Miinzing, W. 45, 65,327, 341 Mulford, R.N.R. 175 Mullen, J.G. 219 Muller, J. 125, I89, 247, 269 Munjal, R. 390 Murani, A. 81,202, 276, 286,
325, 89, 92, 109, 264 Muratova, I.A. 213, 363,
374-378, 386, 387, 390, 391 Murday, J.S. 252 Murnick, D.E. 380, 385, 392,
393 Murphy, D.W. 247,269 Murphy, J.P. 213 Mustachi, A. 160, 164 Mydosh, J.A. 154, 181 Myers, H.P. 136, 150 Myles, K.M. 106, 107, 127
Nace, D.M. 82° 84, 114, 115, I17, I85
Nagamine, K. 305, 386-392, 406
Nagamiya, S. 390,406
Nagel, H. 11~115, 119, 174 Nakagawa, Y. 80, 83 Nakai, K. 390 Nakajima, T. 266 Nakamura, K. 32,34 Nanis, L. 326, 328 Naramoto, H. 58 Narasimhan, K.S.V.L. 188,
189, 213 Narath, A. 258 Nasu, S. 183 Naumov, V.G. 152, 164 Neckel, A. 103 Neddermeyer, S.H. 349 N6dellec, P. 248 N6el, L. 293 Negro, A. 66 Nelin, G. 97, 250, 256, 275
277, 282, 325 Nellis, W.J. 182 Nelson, H.G. 326, 328, 329 Nemchenko, V.F. 287, 292 Nemnonov, S.A. 115, 116 Nemoshkalenko, V.V. 136 Nernst, G.H. 70, 7782,84,
91, 93-95, 118, 167, 207, 208, 215, 285, 286
Nesselmann, K. 3 Neumaier, K. 405 Neumann, C.H. 252, 262 Neumann, H. 182, 183 Neumann, W. 58 Niebergall, W. 2 Nieminen, R.M. 387 Niinikoski, T.O. 378, 380-
382, 385, 406 Nikol'ski[, B.A. 213, 363,
373-378, 385-392 Nishida, N. 305, 386-392,
406 Nistic6, N. 108, 136, 150,
157, 265 Nixon, J.M. 1,7,237 Njiman, H. 321-323 Noaek, F. 247, 255, 261 Noer, R.J. 267 Noguchi, S. 114 Nojiri, Y. 390 Norberg, R.E. 22Z 231, 260 Norden, P. 207 Norlin, L.-O. 378, 380 382,
385, 406 Norris, C. 136, 150 Northrup~ C.J.M., Jr. 249,
251
Author Index 343
Nowak, B. 227 Nowick, A.S. 54 Nowik, I. 143, 160, 161, 164 Nozi6res, P. 282,290 Nuovo, M. 329-333 Nuttall, L.J. 201
Oates, W.A. 3, 65, 79, 81, 92, 286, 289, 298, 306, 307
Obata, Y. 258 Obenshain, F.E. 138 Obermann, A. 112, 148, 149,
164, 331, 332, 335, 129- 131, 151
Occhialini, G.P.S. 349 Ochiai, S. 319 Ockers, S.T. 63, 66, 67, 91,
121,329, 330, 21, 22, 29, 3I, 33, 38~10, 51, 55, 246, 325
O'Connell, E.G. 203 Oei, Y. 108 Oesterreicher, H. 223, 247,
269 Oetting, F.L. 209, 210 Ofer, S. 143, 160, 161, 164 O~urtani, T.O. 329 Ohring, M. 155, 164 Ohta, T. 406 O'Keeffe, M. 220, 221, 304,
327 OIl, B.A. 79 Oliver, F.W. 164 Olsen, K.M. 327 Onischak, M. 230, 235, 236 Oppermann, H. 58 Opyrchal, J. 142, 160 Oriani, R.A. 91,283, 287-
289, 292, 293,296, 298, 299, 307, 308, 311, 312, 315, 316, 324
Orlow, A.A. 159, 167 Orth, H. 380-382, 406 Oswald, R.S. 155, 164 Otterson, D.A. 183 Otto, K. 207, 214 Ouseph, P.J. 160, 164 Owen, C. 325 Owen, E.A. 207
Packard, M. 227 Paesold, G. 57 Palczewska, W. 326, 328 Palizzari, C.A. 283 Pan, S.S. 80
Pancini, E. 349 Pankratov, O.A. 199 Papaconstantopoulos, D.A.
108, 111,122, 123, 405,266 Papp, K. 406 Parkin, D.M. 380, 385, 406 Parks, C.D. 170, 171 Parks, R.D. 243, 253 Parlee, N.A. 326, 328 Partom, Y. 216 Pasternak, M. 247, 269 Patterson, B.D. 386-392 Patterson, R.E. 340 Pattison, P. 269 Pauer, W. 7 Pauli, W. 352 Pauthenet, R. 391 Pearson, W.B. 13 Pebler, A. 175, 307, 326, 328,
227 Pedersen, B. 67, 227, 234,
335, 35, 51 Peierls, R. 282, 290 Peisl, H. 2, 7, 40, 41, 49, 53,
57-59, 64 67, 201,212, 252, 14, 15, 32, 33, 276, 311
Pelah, 1. 155, 164 Pelizarri, G. 87, 88 Pelizzari, C. 261,264 Pellis, G.P. 101,129, 133 Pells, G.P. 266 Penfoid, J. 170 Percheron, A. 236 Peretti, J. 79, 204, 216, 271,
280 Perfetti, P. 108, 136, 150,
157, 265 Perkins, G. 376, 377 Perkins, R:S. 112, 113 Perk M.L. 350 Perminov, P.S. 159, 167 Pernesfftl, K. 378, 380-382,
385, 406 Pesch, W. 16 Peschel, I. 223 Pessa, V.M. 136 Pessall, N. 227 Peter, M. 155 Peterson, D.T. 405, 57, 189,
214, 246, 248, 257, 279, 285, 287, 291,300
Petri, R. 58 Petrunin, V.F. 15-19 Petzinger, K.G. 390
Pfeiffer, G. 31, 32, 55, 246, 290, 295
Pfeiffer, H. 57, 58, 63, 65-67 Pfeiffer, J. 201,212 Philibert, J. 274, 276,278-
280 Phillips, W.C. 148, 152, 153,
164 Piccioni, O. 349 Pick, M.A. 39, 64, 66, 201,
11, 13-16, 27, 28, 31-34, 43, 47, 49, 52, 60, 61, 67, 233, 276
Pickett, G.R. 267 Picraux, S.T. 310, 326, 327 Pietronero, L. 223 Pietrzak, R. 287, 291, 296 Pindor, A.J. 189, 261, 262,
266 Piper, J. 342, 343 Pirogov, A.V. 385 387, 390 Placzek, G. 76, 78 Pochmann, W.A. 331 Podgurski, H.H. 315, 316 Podolinskaya, T.A. 310 Poeschel, E. 101, 109, 111,
118, 120, 121, 125, 146 Polcari, M.R. 155, 164 Pollmann, J.. 16 Ponomarev, A.N. 385 Pontiatowskij, E.G. 174,
177 179, 193 Pope, M. 320 Popovic, Z.D. 199 Portis, A.M. 390 Post, W. 405 Potts, R.B. 79 Potzel, W. 138, 162 Poulis, N.J. 259 Pound, R.V. 146, 227, 244,
364 Powell, B.M. 94, 95 Powell, C.F. 349 PowelI, J.R. 1, 236 Powers, A.J. 235 Powers, R.W. 321,319 Prager, M. 208 Pratt, J.N. 274 Press, W. 208 Priestly, M.G. 107, 172, 131 Primas, D. 326, 328, 343 Pr/Sbst, F. 144~146, 15C~152 Prowse, D.B. 160, 164 Pryde, J.A. 40, 41, 29, 33, 55,
61, 62, 89, 213
344 Author Index
Purcell, E.M. 227, 244, 253, 364
Purogov, A.V. 392
Quick, N.R. 406
Raczyfiski, W. 326, 328 Radeloff, C. 312 Radhakrishnan, T.P. 326,
328 Radosevich, C.L. 222 Raghavan, P. 141 Raghavan, R.S. 141 Rahman, A. 77, 85, 87, 88,
261, 264 Rainer, D. 244 Randall, D. 325, 340 Randzio, S. I78 Ransley, C.E. 327 Rao, V.U.S. 184, 185, 246 Rasch, K.-D. 55,58 Rashid, M.S. 15, 53 Rat, J.-C. 287, 290~93 Ratajczyk, l. 326, 328 Ratajczykowa, I. 97, 98, 136 Raub, Ch.J. 124, 125, 170 Rauch, G.C. 43,246 Raynor, G,V. 46 Read, M.E. 376 Rebka, G.A. 146 Redman, H.E. 221 Reed, R.E. 58 Reed, T.B. 246 Regan, D.W. 329, 330 Reichardt, W. 89, 90, 267, 268 Reichart, W. 386 389, 391,
392 Reiermann, B.K. 326, 328 Reigler, P.F. 220 Reilly, J.J. 121, 4, 18, 21, 23,
32, 33, 62, 89, 203,207, 209, 213 215, 218~23, 226- 230, 233~ 237, 238
Reimann, A.L. 213 Repetskii, S.P. 145, 146, 158 Resing, H.A. 245 Rhim, W.K. 263 Rhyne, J.J. 188, 190, 191 Richards, R.J. 316, 317 Richter, D. 212, 213, 222,
267, 274, 275, 280, 281, 283-286, 329, 330, 341,406, 55, 246, 300
Rieder, G. 293 Riedler, A. 7 Rieger, H. 290, 301
Ries, G. 89, 268 Rietschel, H. 89, 90, 245, 257,
258, 267, 268 Rigney, D.A. 274 Rimet, G. 391 Rinn, H.W. 220 Rittenberg, D. 91 Robbins, C.G. I89, 247, 269 Roberts, B.W. 119 Roberts, C.B. 220 Robertson, B. 252 Robertson, W.D. 326, 328 Robertson, W.M. 327 Robeson, R.K. 217, 218 Roddy, 3.T. 246 Rodin, A.M. 227 Roenker, K.P. 237-239,241,
242 Roganov, V.S. 213, 363, 374,
376, 378, 386-392 Roggwiller, P. 386-389, 391 Rohrschach, H.E. 282 Rohy, D. 120, 121, 123, 259 Rollason, E.C. 326, 328 Romand, M. 57 Ron, M. 155, 164 Ron, W. 235 Rorschach, H.E. 246 Rosan, K. 31, 35, 290, 295,
321 Rose, R.M. 43,246 Rosenberg, R. 274, 294 Rosenhall, G. 183 Ross, D.K. 81, 86-90, 202,
256, 276, 277, 279, 286, 325, 329, 330, 335, 89, 92, 94, 109, 150, 261,264
Ross, J.W. 160, 164 Rostocki, A.J. 162, 190, 193 Rothberg, G.M. 155, 164 Rothenberg, J. 248 Rother, H. 271,273 Routbort, J.L. 282 Rovner, L.H. 56 Rowe, J.M. 66, 81, 83-88,
93-95, 97, 98, 110, 267, 271-273, 275-279, 281, 285, 325, 331-335, 94, 260- 264, 266, 269
Rowell, J.M. 244, 261 Rozenfeld, B. 287, 291, 296 Rubbia, C. 352 Rubin, R. 62, 79 81, 84, 223,
279,280, 282, 283, 322, 329, 330, 334
Ruby, S.L. 144 Rud, N. 326, 327 Ruderman, M.A. 169, 175 Rudman, P.S. 204 Riiegg, W. 376, 378-381,
384, 386-391,406 Rush, J.J. 66, 81, 83, 85 88,
93-95, 97, 98, 110, 271 273; 276~279, 281,285, 325, 331 335, 94, 260-264, 266, 269
Ryabchikov, L.N. 327, 329 Ryabov, R.A. 326, 328
Saba, W.G. 35, I17 Sack, H.S. 209 S~iufferer, H. 233, 234 Safanov, V. 326, 328 Safronov, V.G. 215 Sabra, P.R. 246 Saito, H. 226, 227 Saito, Sh. I57 Sakamoto, K. 306, 318 Sakamoto, M. 80, 322, 331,
89 Sakurai, J.J. 350, 352 Salam, A. 352 Salmon, O.N. 325, 340 Salomon, D. 3, 138, 145, 149,
155-159, 164, 267, 271,275, 322, 324, 331,332
Saly, V.I. 326, 328 Salzano, F.J. 1, 201, 203,
217, 230, 233,236 Samarskii, Yu.A. 253 Sander, L.M. 206, 207, 210,
211 Sandmo, H. 35, 117 Sandrock, G. 220, 233 Sankar, S.G. 188, 190, 191,
193 Sansores, L.E. 250, 261 Saridakis, N.M. 236 Sarradin, J. 236 Sasaki, Y. 32,43,51 Sass, S.L. I9, 21, 22, 52-54 Sato, K. 81~ 83, 84 Satterthwaite, C.B. 88, 405,
406, 90, 189, 243, 246-248, 251,257, 258, 264, 265, 267, 268
Sauges, A.A. 320 Sawaoka, Akira I57
AuthorIndex 345
Sawatzky, A. 273,289, 297, 298
Scalapino, D.J. 243 Scarbrough, J.O. 55 Schaefer, H.E. 291, 310 Schaefer, M.H. 236 Sch~itzler, R. 406 Schaller, H.-J. I05, 106, 108,
109, I27 Scharfenberg, R. 58 Schaumann,G. 33, 62, 66,
67, 69, 199, 210, 212, 222, 280, 291,321,323, 329 334, 339, 341, 32, 148, I5l, 276, 286, 300
Schedler, E. 94 Schein, L.B. 405 Schenck, A. 358, 367, 376,
378-381,384, 386-391, 406
Schenck, H. 326-328, 343 Schenk, H.J. 134, 158 Scherm, R. 92 Scherrer, S. 327 Schillaci, M.E. 380, 385, 406 Schiller, P. 303, 331,317,
32I 323 Schilling, H. 376. 378-381,
384, 386 391,406 Schindler, A.I. 108, 111,101,
114, i17, I29, 185, 247, 259, 260, 266
Schirber, J.E. 70, 108, 77, l l l, 188,249, 251-254, 260, 266
Schl~it, F. 57 Schlapbach, L. 236 Schmahl, N.G. 106~ 107 Schmatz~ W. 2, 44, 45, 60, 80-
82, 330, 32, 34, 311, 319 Schmidbauer, E. 187, 192
Schmidt, D.L, 220 Schmidt, F.A, 55, 57, 58,
287, 291 Schmidt, H.G. 267 Schmidt, L.D. 85-87 Schmidt, S. 91 Schmolz, A. 247, 255, 261 Schnabel, D. 40, 41,286 Schneevogl, F. 3
Schneider, J.R. 60, 269 Schneider, T. 243 Schneider, W.R. 223 Schneiders, A. 331
Schober, T. 3, 405, 2, I1, I5- 22, 24, 26, 29-47, 50, 5I, 53, 54, 90, 301,309
Schoeck, G. 301,311 Schoener, G. 238 Schoenfelder, C.W. 213 Schoep, G.K. 259 Schofield, P. 77 Scholtus, N.A. 207 Schreiber, D.S. 137, 23l,
242, 259, 260, 246 Schreiner, F. l, 7, 237 Schreyer, H. 309, 315 Schrieffer, J.R. 243 Schr/Sder, E. 246 Schroeder, U. 79 Schuetz, A.E. 326, 328 Schultz, H. 212, 301, 341,
32, 55, 57, 58 Schulze, K. 55,58 Schumacher, D.P. 170, 178,
157 Schumicki, G. 137 Schurter, W.H. 183 Schwarz, W. 326, 328, 343 Scott, T.E. 15, 53, 54 Scott, W.R. 152 Seeger, A. 3, 290, 300, 301,
303,306, 307, 341,349, 370, 371,376, 38(>382, 386-388, 391,393,406
Segal, E. 186 Seigle, L.L. 109 Seitz, E. 311, 319 Sekine, K. 196 Selivanov, V.I. 213, 363,
373-378, 385-392 Sellors, R.G.R. 274 Selwood, P.W. 85 Serdyuk, A.D. 331, 332 Serneels, R. 21,24,54 Seymour, E.F.W. 247, 252,
254~257, 259, 276, 277, 139 Shalatov, G.A. 19 Shaltiel, D. 143, 161, 164 Sham, L.J. 282, 290 Sharp, R.I, 40 Shavely, C.A. 123 Shaw° J.G. 289, 298 Sheft, I. 1, 7, 237 Shenoy, G.K. 132, 137-144,
146, 159, 160, 161,164 Sherman, D. 325 Sherwood, R.C, 155 Shewmon, P.G. 310
Shih, H.M. 310 Shil'stein, S.Sh. 119, 122;
15-21, 23-26, 185 Shimizu, M. 125 Shinjo, T. 147, 148, 164 Sholl, C.A. 245-249 Shore, H.B. 206, 207, 210,
211 Shreir, L.L. 326, 328 Shtrikman, S. 145 Shull, C.G. 277, 386, 387,
390, 73, 89 Sicking, G. 79, 213, 312, 331,
332, 338, 340, 405, 88, 94- 97, I34, t48-150
Sidorenko, V.M. 287, 29I, 292
Siegelin, W. 121, 122 Siems, R. 6 Sieverts, A. 1, 3, 90, 177, 229 Silverman, P.J. 85, 261, 262 Simmons, M.L. 380, 385 Simon, F. 169, 171 Simons, J. 120 Simons, J.W. 325, 79, lOlo
287, 290 Simopoulos, A. 155, 164 Sines, G. 16 Singe, Th. 120, t30 Singwi, K.S. 77, 146, 223,
274, 378, 387, 406 Sinha, S.K. 85, 87, 88, 261,
264, 269 Sinke, G.C. 209, 210 Sizmann, R. 62, 97, 300, 326,
328, I5, 66, 73, 326 Sj/51ander, A. 76, 77, 146, 223,
274 Skillman, S. 106 SkiSld, K. 3, 87, 88, 250, 256,
267, 271, 272, 275 278, 281-283, 285, 325, 333, 334, 261, 264, 268, 324
Skoskiewicz, T. 108, 111, 73, 90, 164, 167, 169, 177, 185, 187-190, 197,243,247, 249, 251-254, 26t, 262
Sladek, R.J. 320 Slaggie, E.L. 79, 90 Slichter, C.P. 263, 357, 361,
371 Sliwa, A. 182 Slotfeld-Ellingsen, D. 67, 35,
51 Smallman, R.E. 308
346 Author Index
Smialowski, M. 326, 328, 158, 160
Smilga, V.P. 373 Smith, B.J. 249, 250 Smith, H.G. 81, 85-88, 110,
94, 260, 262-264, 266 Smith, R.J. 183, 185 Snayely, C.A. I77 Sneddon, I.N. 14 Sniadower, L. 189, 261, 262 Snoek, L. 62 Snover, J.A. 220 Sobe, G. 58 Sohmura, T. 148, 155, 164 Sokolov, B.V. 213, 363, 374,
376, 378 Sokolov, V.A. 221 Solomon, J.S. 57 Somenkov, V.A. 3, 25, 40,
62, 81M82, 97, 119, 122, 300, 337, 15-2I, 23-26, 34, 66, 117, I85
Someno, M. 226, 227 Somrner, A.W. 289, 297 Soraji6, V. 58 Sorbello, R.S. 274, 282-284,
296 Sosnowska, I. 81, 202, 276,
279, 286, 325, 89, 92, 109, 264
Souffach6, B. 264, 266 Soul6, J.C. 406 Spaeth, G. 56,57 Spaithoff, W. 182, 240 Spanjaard, D. 142, 159 Specht, W. 287, 293 Spedding, F.H. 70 Speed, S.E. 211 Sperling, K. 287, 293 Spillmann, J. 146, 164 Spirlet, J.C. 162 Springer, T. 2, 3, 44, 45, 75,
77, 79 84, 94, 223, 224, 267, 271,273-275, 278, 279, 282-286, 300, 329, 330, 335, 341, 32, 34, 55, 246, 260
Squire, C. 170 Srinivasan, S. 201 Stachurski, Z. 325, 326, 328,
142-146 Stafford, S.W. 117, 125, 314,
315 Stalinski, B. 67, 114, 121,
142, 160, 170-172, 174,
175, 179, 182, 230, 231,240, 241,18, 66, 227
Stanitski, C. 217, 220 Stearns, M.B. 370, 386 Steeb, H. 306, 326, 317, 324 Stegun, I.A. 203 Stein, J.E. 326, 328, 329 Steiner, P. 139, 142, 143 Steinhauser, K.A. 342, 405,
406 Stejskal, E.O. 251, 257, 262 Stell, G. 30 Stelmach, S. 326, 328 Stensland, W.A. 57 Stephan, K. 1,236 Stephens, D.R. 157 Sterlyadkina, Z.K. 215, 220 Stevens, J.G. 132, 133, 137,
138 Stevens, R. 254 Stevens, V.E. 132, 133, 137,
138 Stevenson, E.C. 349 Steward, S.A. 281, 222, 223 Stewart, G.R. 247, 269 Steyert, W.A. 147, 152, 155 Stocks, G.M. 136, 150 St/Shr, J. 142, 159, 160, 164 Stokkeland, O.E. 234, 335 Stoll, E. 243 Stoneham, A.M. 199, 210-
216, 291,376, 294, 299 Stott, M.J, 199 Strange, J.H. 248 Street, J.C. 349 Strickland, G. 214, 215, 230,
233 Stritzker, B. 3, 85, 88, 89,
2, 13, 30, 55, 62~ 65, 90, 187, 188, 243, 247, 249-257, 261 263
StrBbel, B. 159, 238, 331 Stroka, A. 173, 174, 176, 18I Stronach, C.E. 380, 381,
385 387, 390, 392, 393, 406 Strongin, M. 57 Stross, T.M.' 326, 328 Stiiwe, H.P. 326, 328, 309,
310, 316 Stull, D.R. 209, 210 Stump, N. 45, 62, 80--83, 94,
96, 98, 223, 250, 257, 274, 277, 279, 280, 330, 337, 60
Stupin, D.Y. 110 Sturges, C.M. 306, 318
Subbotina, N.I. 326, 328 Subramanyan 327 Suetin, V.A. 373 378, 385-
392 Suganuma, T. 212 Sugeno, T. 320 Sugimoto, K. 390, 319 Sugr6, E. 350, 352, 354 Suhrmann, R. 137 Suits, B. 160, 164 Sun, T.-H. 326, 328, 343 Sundfors, R.K. 238 Sussmann, J.A. 199, 204, 217 Suuberg, E. 235 Suzuki, T. 21, 24, 54 Svensson, B. 69, 171 Svist, E.h 315 Swalin, R.A. 29, 32 Swartzendruber, L.J. 143,
149, 155, 164 Swendsen, R.H. 158, 159,
284 Swets, D.E. 326, 328 Swift, W.M. 186 Swisher, J.H. 213 Switendick, A.C. 3, 79, 101,
106, 108-111, 114, 117, 118, 122, 127, 135, 136, 150, 157, 173, 177, 192, 261, 90, 126, 133, 187, 243,259, 265
Sykes, C. 326, 328, 343 Sykora, 13. 58 Szafraflski, A.W. 108, 111,
90, 164, 167, 169, I71, 181, 183, 185, 187 I89, 191, 195-197, 249, 251-254
Szk~arska-Smiatowska, Z. 326, 328
Szklarz, E.G. 259
Tada, M. 327 Takada, T. 147, 148, 164 Takagi, Y. 114 Takamura, J. 55 Takano, S. 21, 24, 54 Takeshita, T. 190, 191, 193,
208, 213,223, 229 Takeuchi, T. 114, 386-389 Takita, K. 306, 318 Talbot, D.E.J. 327, 310 Talbot-Besnard, S. 326, 328,
329, 387, 388 Tamminga, Y. 216 Tanaka, J. 217, 220
Author Index 347
Tanaka, K. 121-123, 157, 261, 337
Tanaka, S. 406 Tanaka, T. 117, 185 Tanihata, I. 390 Tanner, J.E. 251, 257, 262 Taxhet, H. 326, 328, 343 Taylor, H.S. 97 Taylor, J.C. 352 Taylor, N. 213 Taylor, R.D. 147, 152, 155,
337, 341 Tedrow, P.M. 253 Teichler, H. 376, 377, 379-
382, 388, 405 Tenckhoff, B. 3 Terada, K. 220 Teuchert, W.D. 81-83, 92,
94, 96--98, 269 Tewary, V.K. 10, 15 Thoma, K. 161, 164 Thomas, D.H. 107 Thompson, A.W. 179, 315 Thompson, D.O. 65, 66, 30,
33 Tien, J.K. 316,317 Timofiejeva, G.W. 159 Timoshenko, S.P. 2l Titcomb, C.G. 40, 41, 90,
183-185, 29, 33, 55, 61, 62 Tkasz, M. 164, 167, 174, 177,
178, 181, 189, 191 Tobin, R. 267 Tocchetti, D. 81, 82, 88, 202,
276, 286, 325, 330, 89, 92, 109, 264
Toda, G. 325, 196, 287 Toepke, I.L. 189, 243, 247,
258 T6pler, J. 267, 283-286, 341,
406, 55, 246 Tombrello, T.A. 65 Tomita, K. 239, 363, 364 Tompkins, F.C. 326, 328 Torgeson, D.R. 405 Torrey, H.C. 227, 245, 246,
364 Toth, G. 79 Toth, L.E. 105 Tr~iuble, H. 298, 391 Tranchant, J. 221 Tretkowski, J. 2, 33, 40, 43,
45, 199, 323, 324, 334-337, 339, 341, 30, 66, 286
Treyrand, A. 189
Treyvard, A. 247, 269 Triftsh~iuser, W. 380, 385,
406 Trinkaus, H. 59, 32, 34 Tripp, R. 230 Trombe, F. 175 Trousdale, W.L. 152 Trowse, F.W. 285,301 Trzebiatowski, W. 114, 121,
170-172, 182 Trzeciak, M.J. 227, 229 Tsebro, V.I. 253 Tsong, I.S.T. 89, 213 Tsuchida, T. 186, 120, 121,
256, 266 Turban, L. 282, 290
Uemura, Y. 406 Ulmer, K. 132 Umanskij, Ya.S. I85 Urey, H.C. 91 Uribe, F. 222, 223
Vagelatos, N. 66, 93 95, 269 Van Dam, J.E. 254 Van Diepen, A.M. 155, 164,
179, 188 190 Van Dyke, J.P. 245, 247, 257,
262 Van Holsbeke, G. 55,58 Van Houten, R. 229 Van Hovel L. 76, 78, 248, 268 Van Kampen, N.G. 26, 29 Van Landuyt, G. 146, 164 Van Mal, H.H. 1,4, 7, 208,
209, 211, 220, 222,223,229, 236, 237
Van Vleck, J.H. 229, 230, 363
Van Vucht, J.H.N. 182, 183, 211, 222
Vangham, D.A. 177 Vannice, M.A. 134 Vardiman, R.G. 58 Vas, A. 160, 164 Vaughan, D.A. 123 Vaughan, R.W. 263, 406,
117 Veleckis, E. 40, 57, 62, 209,
285, 286, 293, 298 Verdan, G. 79-81, 84, 204,
279, 322, 329, 330, 334 Verdini, L. 331, 290, 295 Verghese, K. 34
Verhoeven, J. 274, 285, 300 Vetrano, J.B. 246 Vetter, K. 306, 313-315 Vibrans, G. 326, 327, 309,
310, 316 Videm, K. 223 Vieland, L.J. 246 Vineyard, G.H. 219, 220,
249, 337, 342 Vinhas, L.A. 223, 282, 283 Viswanathan, R. 124, 125 V61kl, J. 1, 2, 3, 5, 10, 32, 33,
40, 43, 45, 53, 62, 63, 65-67, 69, 70, 79-8I, 84, 85, 89, 92, 108, 111, 134, 135, 145, 157, 159, 169, 199,201,210, 212, 213, 22l, 222, 233, 254, 256, 280, 284, 291,300, 321-327, 329-341,343, 388, 405, 406, 1, 2, 11, 13- 15, 26, 30, 32, 33, 41, 57, 63, 66, 73, 148, 149-151, 259, 260, 265, 276, 277, 286, 300, 317, 324
Vogt, E. 129 Voitl~inder, J. 133 Vold, C.L. 58 Von Baltz, R. 208 Von Brummer, O. 124 Von Ellerbrock, H.-G. 326,
328, 309, 310, 316 Von Maltzahn, G. 127
Von Minnigerode, G. 248
Von Samson-Himmelstjerna, H.O. 77, 159
Von Stackelberg, M. 325, 77, 142, 144, 145, 207
Von Turkovich, B. 312, 313 Vook, F.L. 310, 326, 327
Vorderwisch, P. 79, 89, 90, 97, 98
Vuillemin0 J.J . 107, 136, 172, I31
Vykhodets, V.B. 325, 340, 287
Waber, J.T. 124 Wach, S. 326, 328, 288 Wagner, C. 75, 83, 111, 123,
134, 136, 207, 287, 293 Wagner, F.E. 3, 131, 132,
137-141, 144-146, 149-152, 160-162, 164
348 Author Index
Wagner, H. 2, 5, 7, 9, 10, 13, 18, 19, 21-23, 25, 27, 29, 31, 40-42, 200, 205, 206, 324, 11, 13, 32, 33, 41, 73, 109, 276, 277
Wagner, R. 326,328 Wagner, U. 137, 149, 151,
164 Wagner, V. 81, 83, 96, 98 Wahl, W. 406 Waide, C.H. 203,235 Wainwright, C. 15 Waite, T.R. 67 Wakabayashi, N. 212, 213,
222, 223, 267, 273, 274, 280-283, 286, 329,330, 341, 30O
Wakamori, Koji 157 Wakiyama, T. 363, 379 Walker, E. 380-382, 406 Walker, L.C. 209, 210 Wallace, W.E. 3, 67, 112,
119, 121, 122, 169, 170, 174-180, 183-186, 188-191, 193, 110, 117, I72,208, 222, 223,229
Walsh, P.T. 160, 164 Walter, R.J. 40, 41, 66, 15,
31, 55 Walz, F. 291, 306-309, 311 Wampler, W.R. 110, 406,
309 Wanagel, J. 41, 58, 59, 64-66,
19, 21, 22, 52-54, 276, 311 Wang, T.H. 238 Wang, Y.L. 186 Wanzl, W. 112, 148-150,
164, 129-13I Warf, J.C. 211, 221 Wasilewski, R.J. 342 Wassernaar, T. 159, I69 Waszczak, J.V. 247, 269 Watanabe, N. 81, 83, 84 Watson, R.E. 143, 149, 155,
164 Wayman, C.M. 54 Weale, K.E. 160, 191 Weaver, H.T. 245, 247, 257,
262 Weaver, J.H. 405 Weaver, W. 279 Weber, W. 79 Wedler, G. 137 Wegener, H. 132, 138, 139,
141, 142, 145, 146, 158
Wegner, F.J. 20 Weinberg, W.H. 86~8 Weiner, J.H. 216,217 Weiner, L.C. 306 Weise, G. 58 Weiss, J.A. 108, 110, 127 Weiss, R, 252, 335 Weissenberg, A.O. 349, 352,
354 Weissman, Y. 204, 217 Welter, J.-M. 98, 405, 29-32,
34, 37, 47, 55, 57, 58, 61, 246, 269
Wenzl, H. 3, 98, 405, 2, I1, 15, 19, 20, 30-34, 43, 46, 47, 49, 55, 57, 58, 60, 6t, 233
Wernick, J.H. 149 Wernicke, H.-J. 105 Wert, C. 3, 65, 66, 218, 220,
322, 337, 2, 30, 31, 33, 35, 36, 38, 39, 108, 109, 286, 305, 317, 320
Wertheim, G.K. 131, 142, 143,147-149, 152, 155,164, 192
West, K.W. 160, 164 Westendorp 183 Westlake, D.G. 63, 66, 67,
92, 119-122, 137, 142, 143, 159, 160, 164, 238, 329, 330, 21-25, 29, 31-33, 38~40, 51, 53, 55, 117, I85, 214, 246, 290, 295, 325
Wever, H. 296 Weyl, H. 352 White, J.G. 246 Whitney, E.D. 215 Whitton, J.L. 30, 33, 34 Wiberg, E. 215 Wicke, E. 3, 70, 79, 112, 148,
149, 164, 213,221,256, 325, 326, 331, 332, 335, 340, 2, 73, 77-82, 84, 85, 89, 91, 93-96, 118, i28-131, 134, 137, t39, t40, 148, t50, I5t, 167, 207, 208, 214, 215, 285, 286, 293
Wicklund, A. 246 Wickman, H.H. 142 Widmann, A. 221, 325, 340,
287 Wiedersich, H. 311 Wigand, M. 380-382, 406 Wilkins, J.W. 243 Wilkinson, M.K. 277, 73, 89
Wilks, J. 114 Williams, E,J. 99 Williams, H.J. 155 Williams, R.W. 136, 150 Williams, W.D. 247,
252-256, 262, 276, 277, 139 Williamson, D.L. 140, 152,
153 Winsche, W.E. 203 Winter, H. 89, 268 Winter, J. 361,366 Winterkorn, M. 55, 58 Wipt~ H. 3, 96, 145, 155-159,
164, 209, 212, 267, 271,275, 322, 324, 327, 329-333, 339, 341,405, 2, 29, 31, 32, 35, 38, 55, 246, 273, 276, 277,
286, 288-295, 298-300, 321 Wirtz, K. 283, 284 Wise, M.L.H. 111 Wiseman, C.D. 246 Wisner, W. 58 Wigniewski, R. I60, 162, 167,
t73,179, 18t, t83, 185, I87, 189-I91, 193-I96
Wiswall, R.H. 3, 119, 121, 123, 2, 4, I1, i8, 21, 23, 32, 33, 62, 89, 201, 203, 209, 213-215, 218, 219,222,223, 226, 228, 230, 237, 238
Witte, H. 327, 378, 380, 121, 122
Witte, W. 304, 327, 338, 339 Witts, A.D. 160, 164 W/Sger, W. 39, 48 Wolf, D. 245-250, 364, 365 Wolf, G. 112, 124, 172, 177,
187, 259, 260, 267 Wolf, H. 253 Wolf, S. 237 Wolf, W.P. 137, 159 Wollan, E.O. 190 Wollenberger, H. 32 Wollenweber, G. 70, 213,
221,325,338,340, I49 Wombacher, P. 58 Wood, J.H. 106 Woods, A.D.B. 80,83,94,95 Woolley, R.L. 233, 235 Worsham, J.E.,Jr. 277, 73,
89 Wortmann, G. 3, 131, 138,
145, 147, 149, 151-155, 157-159, 162, 164, 267, 271,275,322, 324, 331,332
AuthorIndex 349 \
Wray, E.M. 10i, 129, 133, 266
Wriedt, H.A. 91, 311, 312, 315
Wu, C.S. 352 Wucher, J. 169, 171, 129 WiJhl, H. 3, 85, 88, 2, 13, 30,
55, 62, 65, 187, 243, 252, 261-263
Wtithrich, C. 303,307 Wulft, J. 43, 246
Yafet, Y. 258 Yakel, H.L., Jr. 171 Yamada, M. 69, 70 Yamada, R. 81, 83, 84, 19,
20, 35, 38 Yamaguchi, M. 406 Yamaguchi, S. 35 Yamakawa, K. 327 Yamamoto, I. 406 Yamanaka, K. 226, 227
Yamashita, M. 55 Yamazaki, T. 305, 386-392,
4O6 Yang, C.N. 352, 99 Yasui, M. 125 Yasuoka, H. 391,392, 406 Yates, B. 101, 129 Yeater, M.L. 80 Yoshida, K. 169, 175 Yoshida, T. 289, 298 Ypma, M.R. 285 Yu, W.-S. l, 233, 235, 236 Yukawa, H. 349, 350
Zabel, H. 3%41, 48, 49, 252, 32, 33
Zakosarenko, V.M. 253 Zamir, D. 182, 242, 247, 252,
255-257, 259, 276, 277, 32, 139
Zanowick, R.L. 119, I21, 122, 170, 174, 176, 177, 180
Zapp, P. 323
Zaremba, E. 366,406 Zbasnik, J. 79, 108, 110, 111,
136, 150, 157, 133, 260 Ze/linger, A. 331 Zemlyanov, M.G. 25, 40, 62,
80-82, 97, 330, 339, 15-20 Zener, C. 218, 220, 337 Zhukov, V.A. 373-378, 385 Ziegler, W.T. 246 Zierath, J. 67, 37, 38, 117 Ziflstra, H. 169, 182, 183 Zimmermann, G. 70 Zimmermann, G.J. 108, 109 Zimmermann, M. 107, 1ll,
259, 260 Zitter, H. 326, 328, 343 Zogal, O.J. 240, 241, 252,
254, 256, 257, 335, 227 Zu Putlitz, G. 380-382, 406 Ztichner, H. 200, 325, 329
333, 335, 340, 55, 61, 62, 73, 79, 140, 142 151
Zvonkov, A. 405
Subject Index
Page numbers for this volume are indicated by italics. All other page numbers refer to Hydrogen in M e t a l s I : Basic Properties, Topics in Applied Physics, Vol. 28, ed. by G. Alefeld, J. V61kl (Springer, Berlin, Heidelberg, New York 1978)
Absorption heat pump using LaNisHx, Mg2NiH ~ 4
Absorption isotherms of H in Pd, effect of deformation on 312,313
Absorption of H in Fe 3 1 6
Absorption process, acceleration by surface activation 180
Accuracy of N M R technique 254
Acoustical phonon dispersion curves see pho- non-dispersion curve(s)
Acoustical phonons 90-98 - - of Nb 93 - - o f N b D x 93
of TaD x 92 Activation energy
, efl'ective (modified by traps), for diffusion 324, 325
- - for cold-work aftereffect 302 for diatomic interstitial-hydrogen comple- xes 301,312
- - of M e - H complexes in fcc metals 315 of Ti-H, T i -D complexes in FeTi alloys 317, 318
Activation energy for diffusion of H, D i n C o 306
- - H, D in FePd alloys 313 - - H, D in Nb (a phase) 329
H, D in Nb (fi phase) 341 - - H, D i n N i 304, 326
H, D in Ta (a phase) 159, 331 - - H, D in V (a phase) 333
- - H , D , T i n Pd 145, 149 - - H, D, T in Pd l_~,Agy 145 - - H from line narrowing in N M R experiments
240 - - H from T I in N M R experiments 244, 247,
261,262 - - H in Fe (c~ phase) 329 - - H in Fe (y phase) 342 - - H in Nb (c(phase) 256 - - H in Nb, Ta, concentration dependence of
256, 336, 337 - - H in Pd (~ phase) 325
H in Pd (c(, fl phase) 255
- - H in Pd0.ssAu0.45 145 - - H in Pd0.,vCuo.53 (fcc, bcc) 342 - - I,i in Pd0.gRh0.1 145 - - H in Ti (bcc, hcp) 342 - - H, theory 203, 211-213, 216, 217, 219, 221,
222 - - muons in ct Fe 388, 389 - - m u o n s i n Cr 392 - - m u o n s i n Cu 376 - - T in Nb (c~ phase) 330
T in Pd l_yCu~, 145 - - T in Pd I _yNi~. 145
T in Pd 1 _~.V.~. 145 Activity 166, 167, 197 - - coefficient 166, I68 Ag - - , diffusion coefficient of H in 145 - - , effective charge number Z* of H. D in 291 AI' , isotope dependence of 294
- - , diffusion o f m u o n s in 384, 385, 394 - - , muon ium precession frequency in 374 AI alloys, hydride formation of 221 Alanate 212, 221 Alcoholic solution of HC1 and H2SO 4 as elec-
trolytes 62 AIH~
, enthalpy and entropy of formation of (A1H3) 209, 210
- - for H storage (A1H3) 220, 221 , H density in (A1H3) 216
- - , superconductivity in (A1H) 247, 248 Alkali metals - - , double hydrides of, for H storage 217 - - , hydrides of, for H storage 217, 218 Alkaline earth metals and alloys, hydrides of,
for H storage 218-220 Amplitude of vibration of H, D in Pd 89 Anelastic relaxation 33, 36, 55, 62
see also Gorsky effect and Snoek effect Anelastic relaxation strength 32
see also Gorsky effect, relaxation strength Anelastic response (Gorsky effect) 11, 13
see also Gorsky effect Anelastic strain 46
352 Subject Index
Anharmonic effects in PdH x, PdD~ 264 Anionic hydrogen 178 Anionic model 105, 127, 173, 179 Anomalies of H diffusion at higher tempera-
tures 222-224 Antibonding states 117, 118 Antineutrino 350 Antiparticle 350 APW method 173, 133 Arrangement of hydrogen - - , disordered 11
, ordered l l Arrhenius relation, deviation from 213, 341 Asymmetry coefficient for positron emission
353 - - , effective 354 Atmosphere of interstitials around dislocations
311 Attempt frequency 219, 301 Attractive interaction see Interaction 197Au M/Sssbauer line - - , isomer shifts of, in Pd I _vAgyH~ 152
, isomer shifts of, in PdHx 151 Austenitic steel, isomer shifts of STFe
M6ssbauer line due to H loading in 155 Automotive propulsion, hydrides for 233~35 Availability 2, 3 - - , l o s s of 6 Axial asymmetry parameter see Nuclear
magnetic resonance Axial ratios of orthorhombic Tal l (/?-phase)
19
Background gradients in NMR see Nuclear magnetic resonance
Baekscattering spectrometer 283,341 Backscattering technique 267 BaH> dissociation temperature of 220 Band modes of dissolved H see Acoustical
phonon dispersion curves Band shifting, screening induced 133 Band structure
- - calculations 105, 106, 108-111, 116-119, 122, 123, 125, 126, 135, 136, 150, 192, 133, 187
of CrH~, 125, 126 - - o f M n H x 125, 126
of Pd based systems 111, 112, 150 - - of PdHx 108 111, 150
of ScH> VH2, YH 2 118 of Ti, TiH:~ 116-119 ofTi l_yVvH x 116
- - of VHx 122, 123 Battery-related uses ol hydrides 236 BeHx for H storage 218
Bending modes 21 - - for foil 44 - - for wire 44 Berg-Barrett x-ray topography 58, 59
Bi - - , diffusion of muons in 385, 394 - - , transverse relaxation rate of muons in 384 Binding energy - - of C-H, C-D complexes in Ni 309 - - of Fe-H complexes in NiFe alloys 312
- - of H on edge dislocations in Fe 307 - - of H to dislocation traps in Fe 318,319
of H to regions of dilatational strain 311 of H-trapping 338
- - of H -V complex in Nb 326 - - of N-H, O H and O D complexes in Ta
32i - - of N-H, O-H, O-D and H - H complexes in
Nb 320,321 of O-D complex in V 321
- - of two different H H complexes 323 Blocking of sites in H diffusion 255, 323, 334,
335, 148 Bohr magneton 295, 351 Bonding states 109, 117, 118 Born-von Karmann model 85, 95 Borohydrides for H storage 212, 22! Boundary conditions 9 11, 15-17, 19 - - , periodic 9, 21, 22 Boundary value problem 12, 13, 18 Bourdon manometer 165 Bragg reflection 47 Bragg-Williams approximation 99, 103 Bravais lattice 269 Breakthrough time 141 Brinkman-Meechan analysis 309 Bulk modes see Elastic modes Bulk modulus, changes due to H, D 91
C (graphite), muonium precession frequency in 374
Ca alloys with Mg, AI, La, noble metals, hydrides of, for H storage 220
CaH x - - , dissociation temperature of (Call2) 220 - - , enthalpy and entropy of formation of
(Call2) 209 - - for H storage 220 - - , H density in (Call2) 216 - - , hydrolysis of 203,204 Call2 + H20, H density in 216 Calorimetric measurements 197 - - on NbH~ 32 - - on TaHx 38
on VHx 22
Subject Index 353
CaNi~, hydrides of, for H storage 220 Canonical ensemble of H in metals 22, 29 Carbide(s), trapping of H in Fe by 315 Carbon monoxide inhibiting H uptake of
hydrides 139, 223 Carnot efficiency 7 Carrier density modulat ion 295 Carr-Purcell-Meiboom-Gill (CPMG) pulse
technique 253-255 Catalysis, hydrogen-transfer 134 catalyst
, hydriding 215 , transference 78, 214
Cathodic saturation 183, 187 CeC%H:, for H storage 222, 223 C - D complex in Ni 309-312 - - , binding energy of 309 - - , dissociation energy of 309 - - , i s o t o p e effect of 309-312 - - , magnetic aftereffect relaxation spectrum of
308 CeCo2, magnetic properties of 186 CeCos, effect of degassing on lattice parameter
of 183 CeD x - - , acoustical dispersion curves of 97, 98 - - , optical dispersion curves of 97, 98 CeF%
, Curie point of 188 - - , magnetic properties of 189 CeFe2H 4 - - , Curie point of 188 - - , magnetic properties of 188-190 CeH:, - - , electrical conductivity of (Cell3) 175 __ Hall coefficient of 177 - - , H density in (Cell3) 216 - - , magnetic properties of(Cell3) 175 - - , optical modes in 90 CeNis,~H solubility in 185 C Hcomptex in Ni 300, 307-312 - - , binding energy of 308, 309 - - , dissociation energy of 309 - - , isotope effect of 309-312
, magnetic aftereffect relaxation spectrum of 307, 308
Channeling 327 , determination of interstitial position of
D by, in Cr, W, Mo 327 - - of D in Cr, W, Mo 327 Chemical potential - - , molar, ,of molecular H 166 - - of dissolved H 322, 276, 285, 286 - - - - in Pd 74-77, 99,100 - - - - in Pd alloys 119
, s tandard molar (atomic H) 166 of gaseous H 186
Chemisorbed hydrogen - - , dissociation of 135 - - , isotope effects in Pd of 97, 98 - - , molecular state of 87 Chemisorption of H - - , model calculation of, on Pt surfaces - - on Pd surfaces 85-88
, dissociative 134 Chudley-Elliot model 269, 276 Clausius-Rankine cycle 2, 4 8 - - lorwater 4 - - , Mg2NiH, used in 7, 8 Cleavage 46 Cluster(s) - - , formation of, in PdH, 113 - - , geometry of 321-323 - - ofinterstitials 320
of O i n T a 319,320 - - of vacancies 308 Co
86, 87
, activation energy for diffusion of H, D in 306
- - , diffusion and location o fmuons in 391-394 - - , effect of muon on conduction electron spin
density in 394 , hcp-fcc transition in, change of magnetic
field due to 391 - - , solubility of H in polycrystalline 314 Coconduction 160, 191 CoDx, magnetic aftereffect relaxation spec-
trum of 304, 305 Codeposition of H and Pd 250 Coexistence curve see Phase diagram COHx, magnetic aftereffect relaxation spectrum
of 304, 305 Coherency stress(es) 15, 19, 20, 22, 26, 29, 40,
48, 276 Coherent phase separation 26, 13, 33 Coherent states 13, 15, 26, 28, 40 Coherent tunneling 197, 204, 208, 384, 394 Cold-work aftereffect 301,306 Cold-work peak in Fel l x 317-319 Combust ion engine 216 Compatibility relations 14, 21 Compressibility of H gas 158, i6 i Compressor for H, hydrides as 236 Concentration determination of H 63, 64, 251 Configurational entropy 97 Content of H in hydrides 215, 216 Continuity equation 34 Core polarization 258 Correlation function(s) 363 - - , dipolar field 244
354 Subject Index
Correlation time for muon diffusion 364, 371, 382
Correlations of protons 30 Cosmic radiation 349 Coupling parameters, elastic 200 Cr
, correlation times in 392 - - , diffusion and location ofmuons in 39~394 - - , solubility of H in 123 - - , trapping ofmuons in 393 CrDx, formation pressure of 178 CrHx - - at high H pressure 177-I79 - - , decomposition enthalpy of 177
, decomposition pressure of 178, 179 - - , electrical resistivity of 178
, electronic density of states of 125, 126 , electronic specific heat of 124-126
- - , enthalpy of formation of 178 - - , entropy of formation of 178
, equilibrium pressure of 177 , formation and decomposition conditions of
177-179 , formation pressure of 178
- - , free energy of formation of 177, 178 , heat capacity measurements on I77 , lattice structure of 124
- - , magnetic susceptibility of 124-126, 170 , mass spectrometry on I78
obtained by electrochemical method 177, 179
, reconstructive transition in 177 , superconductivity in 124
- - , x-ray investigations on 178 - - , x-ray spectroscopy on 124 Critical behavior 13 Critical field
for superconducting PdH x 253 - - for superconducting Th4H~5 258 Critical point - - of Hinmeta ls 25,40~41,199,324,277
of PdH x 82 Critical region
of NiH~. 174 of Ni0.gCu0.1H x 175
Critical slowing down of H diffusion 37, 46, 198, 199, 334, 335
Cross sections for neutron scattering 76, 77, 268, 270, 272, 274
Crystal field interaction see Crystalline electric field
Crystal field splitting see Crystalline electric field
Crystalline electric field (CEF) 136, 163, 179, 180
, ground state of 4f-ions in 136, 137, 159, 160 - - states in rare earth hydrides 159
Crystalline electric field (CEFi studied by M6ssbauer spectroscopy on 16°Dy, 166Er in YH 2 159, 160
- - on 166Erin ErH 2 159, 160 - - on 166Er in ZrH~. 5 160
CsH~ for H storage 217 Cu -- , comparison between H- and muon-diffusion
coefficient in 377 - - , diffusion and location ofmuons in 374~-379,
393, 394 - - , diffusion coefficient of H in 376 378
, diffusion coefficient of H in, isotope depen- dence of 339
, -, comparison with theory 221,222 , effective charge number Z* of H in 291 , muonium precession frequency in 374
- - , muons on octahedral interstitial sites in 379
, precession wiggles in 374 - - , quadrupole effects in 378, 379
, shifting energy in 377 - - , transverse polarization in 378 - - , tunneling transitions in 376, 394 Curie point - - of Gd 176
ofNdCo2H ~ 185 ofNdH2, EuH 2 177
- - ofNdNi2, NdCo 2 186 - - of Ni 326
of NiH~, Ni 1 ).FeyH x 193, 194 of Pd+0.002 at.% Fe 181 of RF%, RFe2H 4 compounds (R= rare earth) 188
- - of RFe 3, RF%H 3 compounds (R=rare earth) 191
- - ofThvFe 3,ThvFe3H:, 193 of Th6Mna3Hx 191 o f U H 3 182
- - of Y6Mnz3 191 Curie-Weiss law 31, 43 cw-resonance absorption 232
d-band, filling up of 184 Debye process 291 Debye temperature 243 - - of Pd, PdH~. 260, 264 Debye-type cutoff 20 Debye-Waller factor 77, 87, 270 - - , static 58 Decay channels of muons 354 Decay mode of particles 351,352 Decay reaction of muon 352
Subject Index 355
Decomposition kinetics of NiHx 160 Decomposition pressure - - o fCrH x 178, 179 - - of Ni l_yFe.,H,, Ni l_~,FeyD x 176 - - of NiHx 160, 174 - - o fPdH x 81,205 - - of TiFeH~ 205, 224 - - of ZrH~ 2II - - ofZrNiH e 211
see also Pressure-composition isotherms, Dissociation pressure
Defects in the hydrogen superstructure 29
Degassing (of samples) 58 de Haas-van Alphen effect on Pd 132 Dehydrogenation, rate of 135 AK-factor 219 Demagnetizing field(s) 357, 367, 372 Demagnetizing tensor 368 Density fluctuation modes 324
see also Fluctuations Density of H 215 - - in hydrogen gas, liquid hydrogen, water,
liquid ammonia, LiH, Nail, MgH> Mg2NiH 4, Call2, Call 2 + H2O, A1H 3, LiA1H,,, Cell 3, Till 2. TiFeH1.931, LaNisH6.7, VH 2 216
Density of states, electrmaic 102-106, 112, 114, 243
- - at the Fermi level, of Pd alloys 172 --, connection of H absorption capability with
172 - - o fCr (bcc, hcp) 125 - - of CrH~ 125, 126 - - of MnH~ 125 - - of Pd 108,111,135 - - of PdH~ 107, 108 - - ofScH2, VH2, YH 2 118 - - ofstoichiometric PdH 109, 111, 135 - - of Ti(fcc) 117, 119 - - ofTi (hcp) 116, 119 - - of TiH~ 117, 118 - - o f V 122, 123 - - o fVH x 118, 122, 123 Density of states, phonons see Phonon density
of states Depolarization of muons - - , fast 356 - - in ferromagnets 356 - - , kinematic 354, 358 Depth profiling 326 Desorption of H 213 - - from Ta, Ti 213 Destructive action of gaseous hydrogen 161,
162
Deuteron - - , gyromagnetic ratio of 351 - - , magnetic moment of 351 - - quadrupole interaction see Electric
quadrupole interaction - - , quadrupole moment of 351 - - , rest mass of 351 - - , s p i n o f 351 Deviation of H-diffusion coefficient from
Arrhenius relation 341 - - for Nb-H 213, 341 - - f o r T a - H , D 341 Diatomic complexes, orientation aftereffect of
293, 300, 301, 307-318 Dideuteride of V 21, 26 7 diffractometr~¢ 58-60
on NbH~ 32, 49, 59, 60 Diffuse scattering - - , Huang, of x-rays 58, 59, 64 - - intensity 58 - - of neutrons 58, 60 - - of neutrons on NbD x 60, 61 - - of x-rays 58 - - of x-rays on NbH~ 59 Diffusion aftereffect 294, 299, 300, 304-306,
313, 314, 318 - - in CoHx, CoD~ 304, 305 - - in FeH~ 306 - - in F%_yPdyH~, Fel_yPdrD~ 313, 314 - - in NiH~, NiD~ 303, 304, 308 -- , relaxation time of 300 Diffusion coefficient 36, 37, 46, 47 - - , comparison between H- and muon-, in
c~-Fe 387-389 - - , comparison between H- and muon-, in Cu
376-378 - - , comparison between H- and muon-, in Nb,
Ta, V 382-384 - - , dependence on H potential, in Pd 1 _yAgy
147 - - , effective (macroscopic) 37, 46, 47, 32~324,
334, 335, 146 , concentration dependence of, in
Pdo.6Ago.~ 147 - - , - - of NiH~ 196 - - - - of PdH x, as function of H fugacity 196,
' 197 - - isotope dependence of 336-341 - - - - o f H i n Nb, Ta, V 212, 213, 222,338-
34I - - - - o f H i n Pd, Ni. Cu 221,222, 338-340 - - modified by trapping 307 - - of Cinc~-Fe 321 - - of H, anomalies at higher temperatures of
222, 223
356 Subject Index
Diffusion coefficient (continued) -, comparison with theory 212-214, 221,
222 - - of H at high H-concentrations 334`337 - - of H at small H-concentrations 324-334 - - of H by NMR 262
- - of H, concentration dependence of 334` 337
- - of H, D in V (c~ phase) 333, 334 -, comparison with theory 212--214
- - of H, deviation from the Arrhenius relation of 213, 222, 223, 341
- - of H, direct measurement by NMR pulsed gradient method 250-257, 262
- - of H, D, T in Nb (c~-phase) 329-331 - - comparison with theory 212-214
- - o f H , D , T i n Pd 145, 149 - - of H, D, T in Pd l_yAgy 145 - - of H, D, T in Ta (c~ phase) 331,332
, comparison with theory 212-214 - - o f H i n A g 145
- - of H in c~-Fe 326-329, 387 389
- - of H i n C u 338-340
- - of H in Fe (c~ and 7 phase) 342, 343 - - o f H i n N b 281 - - of H i n N i 326, 327 - - of H in Pd (c~ phase) 324~326 - - of H in Pd (c~',/3 phase) 255, 256
- - of H in Pd, influence of alloy components on 150
- - of H in Pdo.v7Ago.za, concentration depen- dence of t46
- - of H in Pdl - yAu~. 145
- - of H in Pdo.47Cu0.s3 (fcc, bgc) 342, 343
- - of H in Pdo.9Rho.1 145 - - of H, influence of structure on 342, 343 - - ofH, N, O i n N b 321 - - ofmuons 364, 372 - - - - in A1 385 - - - - in c~-Fe 372, 385-389 - - - - in fl-PdH0.97 385 - - - - inCr 392, 393 - - - - inCu 374-379 - - - - in group V transition metals (Nb, Ta, V)
379-384, 394 - - ~n Ni 390
- - of T in Pd, dependence on deformation of • 149
- - o f t in Pdl_yCur 145 - - ofT in Pdj_yNir 145 - - o fT in Pdl-yVy 145 - - , reserved isotope dependence of 212, 221,
222, 340 - - , shape dependence of 46, 47, 335
- - , tracer 46, 323, 324, 334-337, 146
- - , - - , concentration dependence of, in
Pd0.60Ag0.40 147
Diffusion equation 34`36, 38, 322
Diffusion flux 137
Diffusion of hydrogen , fluid like 198, 223, 224 , identification of step length of 257, 262,
275-281 - - , information on microscopic mechanisms of
197, 228, 267 - - , - - by neutron scattering 250, 267 - - - - by NMR 250-257, 262
, in Pd, Nb, Ta, V 250-257, 275-281
- - in Pd and Pd alloys 134-151 , isotope effects in 139, I40
, long-range 299 , measurement of, by NMR 227
- - , measurement of, by time-lag methods 140-15I
- - , quantum effects in 321 - - , studied by M6ssbauer spectroscopy 145,
146, 157-159 - - with impurities 283-285 Diffusion of muons - - in AI, Bi, fl-PdHo.97 384, 385, 394 - - in c~-Fe 385-389, 394 - - in Co 392 - - in Cr 385,392-394 - - in Cu 374-379, 394
in group V transition metals ~ 379-384, 394 - - in Ni 390
Diffusion of tritium in metals 148 Diffusion potential 280 - - measurements on H in Pd 289, 290 Diffusion theory, comparison with experiments - - fo rH, D, T i n N i , Cu, Pd 221, 222 - - for muons in Cu 213 - - for NbH~, NbD~ 212-214 - - for PdT:, 213, 221,222 - - for TaHx, TaD x 212-214 Diffusional relaxation see Gorsky effect and
Magnetic aftereffect Dihydride of V 21, 23 dilatational strain field around dislocations,
accumulation of H in 312,212 Dilatation centers 19-22
Dipolar interaction 357, 363, 367-370, 373 - - in c~-Fe 369, 370, 389 - - in Ni 390
Dipolar line narrowing 239-241 Dipole approximation 12 Dipole-force tensor see Dipole-moment tensor
Subject Index 357
Dipole-moment tensor 7, 9, 41, 54, 55, 58, 59, 201, 205, 206, 212, 293, 14, 276
- - , anisotropic 21 - - , isotropic 16 Direct field force 281 Dislocation density - - , change of, by phase transitions 30, 31 Dislocations 14, 26, 28, 29, 39, 48, 301, 302,
306, 307 - - , double kinks in 303, 307 - - , kinks (geometrical) in 303, 307 Dislocation trapping of interstitials 316-319 Dispersion curves see Phonon-dispersion
curves Displacement 7, 54
field 11 - - field, image 16 - - of first-, second-nearest neighbors 366 Dissociation of chemisorbed molecules 135 Dissociation pressures for reaction
FeTi-FeTiH, K K H, Mg-MgH2, MgaCu MgH2 + MgCu z, Mg2Ni Mg2NiH 4, NbH NbH2, Pd PdH0. 6,U UH 3, Vo.9Cr0.aH-V0.9Cr0.1Hz, V H - V H 2 205 see also Decomposit ion pressure, Pressure- composition isotherms
Dissociation temperature of SrH2, BaH 2, Ca l l 2 220
Domain patterns 47,51 Domain structure 19, 29, 51 Domain wall(s) 289, 293-295 - - , long-range interaction in 293 295
, width of 299 Double force tensor see Dipole-moment
tensor Double kink(s) in dislocations 303, 307 Drift-flux measurements 286288 - - o f H i n Pd 286, 287
Drift velocity 275
Drift-velocity measurements 286-288 DTA - - o n N b H x 17, 32
on TaHx 20, 35-38 - - - - , cooling curve 28 - - o n V D ~ 41, 42 - - on VH~ 22,38~40 Ductility, change of, by phase transitions 30 Dufour effect 281
DyCo3H ~ for H storage 223 DyFe 3 - - , Curie point of 191 - - , magnetic properties of 191
DyFe3H3, magnetic properties of 191
DyHx - - , isomer shifts of 161Dy M6ssbauer line in
160 - - , magnetic hyperfine interactions in 160 - - , magnetic properties of 175--177 16°Dy M6ssbauer line in YH2 159 161Dy M6ssbauer line - - , isomer shifts of, in DyH~ 160 - - , magnetic hyperfine interactions in DyH2,
studied by 160
Effective charge number Z* 274 - - , correlation of, with Hall coefficient 296
of H, D in Ag 29I - - o fH, D i n F e 292 - - of H, D i n N b 292
of H, D in Ni 292 of H, D in Pd 293
- - of H, D in Pd-Ag alloys 293 - - o fH , D i n T a 292 - - o f H , D i n V 291 - - of H, D in V, Nb. Ta, concentration depen-
dence of 295, 296 of H, D in V, Nb, Ta, temperature dependen- ce of 294, 295
- - o f H i n C u 291 - - o f H i n Y 291 - - o f H , D , T i n T i 291
of H, D , T in Zr 291 - - of hydrogen in Ag, V, Ta, Fe, Ni, isotope
dependence of 294 Eigenfunction of elastic interaction 18 Eigenvalue p!oblem of elastic interaction 19 Eigenvalues of elastic modes 18, 22 Einstein's diffusion coefficient see Diffusion
coefficient, tracer Einstein's relation 46, 322, 323 - - , generalized 276 Einstein temperatures 338 Elastic constants of NbHx, NbD x 91 Elastic dipole(s) 55, 62 - - energy 293 Elastic energy 12 - - , i n t e rna l 13, 18, 30 Elastic interaction 6, 15, 23, 26, 39, 53, 293, 324 - - , comparison with experiments 39 - - , cont inuum model for 10 - - in finite cont inuum 16 - - in infinite con t inuum 15 - - , range of 20 - - , r3-behavior of 16, 23 Elastic modes 18, 23, 27, 28, 31, 33, 34, 40 - - , bulk 19, 20, 22, 27, 32, 35, 36 - - , - - ofanisotropic crystal 32 - - , degeneracy of 20
358 Subject Index
Elastic modes (continued) - - , macroscopic 19, 20, 23, 27, 31, 33, 35, 36,
47 - - ofisotropic sphere 19, 21, 27, 37 Electrical resistivity - - at high H pressure I80 187
, anomaly of, in PdH x 185, 186 - - - - of Ni I_yC%H.,., Ni I CoyD~ I76 - - - - o fNiH x 174,187, I90
- - , maximum of, in Pd l_~,PtyH~ 185, I86 - - - - ofCrH x 178 - - - - of Nix_yCoyH x, Ni I yCorD~ I76 - - - - ofNil_~.Fe~.H, 181, 182 - - - - of NiH:, I74, t87, 190 - - - - of NJx_yMn),H:~ 180, I81 - - - - of ordered and disordered P d y e H x
182, 183 - - - - of PdHx I60, 167, 183, I84, 189-191 - - - - of PdH~, Pd l_s,AgyH~, Pdl_,,Au:H ~
183,184 - - - - of Pd-Pt alloys 173
- - - - of rare earth, alkaline earth and boro- hydrides 157
- - , change of, by cracks, microcrystallites 180 --,influence of hydrostatic pressure on 181 - - , low temperature measurements of, for in-
vestigation of trapping of H in V, Nb, Ta 326
- - o fNbH x 28, 29, 32 - - , residual 58, 180, 182-184
-, ratio of(RRR) 58 - - , temperature dependence of, of PdH.,
264, 265 Electric field gradient (EFG) 131, 141, 234
- - generated by muons 366 - - tensor 234
- - tensor, principal axes of 235, 239 Electric quadrupole interaction(s) 141,
160-163, 234-239 - - in EuH 2 and YbH 2 160 - - in NpH2+~ 161, 162 - - in VDx, NbD~, TaD~ 23(>239 Electric utility, load leveling in 201 Electrochemical measurements 159, 197 Electrochemical method
- - for formation of CrH~ 179
- - for formation of NiH~ 160, I87, 192 - - for H diffusion measurements 324, I42 Electrochemical permeation method for H-
diffusion measurements 333 Electrode potential of hydride phase 159 Electrolyte(s) 55, 61 - - , alcoholic solutions of HC1 and H2SO 4 as
62 , hydrogen-free 58
Electrolytical (electrochemical) H doping 34, 38, 49, 61, 62, 64, 65 of Pd 249 see also Electrochemical method
Electromigration see Electrotransport Electron diffraction 19, 27 - - on VH x 22
Electron drag force see Electron wind force Electron magnetic moments, interaction of
muons with 357
Electron microscope
- - , phase morphologies in NbH~ studied by 49-51
- - , phase morphologies in TaH~ studied by 52
- - , phase morphologies in VH., studied by 54
Electron-phonon interaction 243 - - in Pd alloys 133
- - in PdHx, PdD~ 90.9I, 129 Electron wind force 281 Electron work function of Pd surfaces covered
with H 86
Electronic interaction 6, 22, 23, 40
Electronic specific heat see Specific heat (electronic}
Electronic structure, similarity of, between Cu and NiHx l~O
Electrotransport - - , failures in metal stripes of integrated cir-
cuits, caused by 300 - - of H in metals 273-304 - - , purification of metals from interstitial im-
purities by 300
Embrittlement, hydrogen I I - - of iron and steel 307, 319 Energy cascading using metal hydrides "/, 2-9 Energy levels of elastic dipoles 293, 294 Energy resolution in quasielastic neutron
scattering 267, 283 Enthalpy - - of decomposition ofCrH x 177 - - of desorption of H from Pd surfaces 86 - - of formation of CrHx 178 - - of formation of fi phase PdH x 82 - - of solution, partial molar 306,314 - - , relative partial molar, of PdH~ I70, 171 - - , standard, of formation of A1H a, Call 2,
LaH 2, LaNisH 6, LiH0 MgH2, Mg2NiH~.2, Nail, TiFeH1.0, TiH,.97, UH3, VH0.2, VH2.o, ZrH 2 209
- - , standard, of formation of NiHo. s, NiDo. s 173
, , isotope effects in 173
Subject Index 359
Entropy of formation - - ofA1H3, CaHz, LaNi5H6, LiH, MgH2,
Mg2NiH,~.2, TiFeHi.o, TiHa.97, UH3, VHo. z,VH2. 0 209
- - o f C r H x 178 - - of NiHo. 5, NiDo. 5 173 - - of PdH x 170, 171 Entropy of solution 95 97 - - , partial molar excess 306,314 Equation of state of gaseous hydrogen at high
pressures 159 Equilibrium isotope effects see Isotope effects Equilibrium pair number 103 Equilibrium pressure - - of CrHx 177 - - ofNiHo.s, NiD0.5 173
see also Decomposit ion pressure, Forma- tion pressure, Pressure-composition iso- therms, Dissociation pressure
ErCo3H ~ for H storage 223 ErFe 2 - - , Curie point of 188 - - , magnetic properties of 188 ErFezHx - - , Curie point of 188 - - , magnetic properties of 188, 189 - - , neutron diffraction results on (ErFezH4)
190 ErFe3H ~ for H storage 223 ErH x 160 - - , 166Er Mtissbauer line in (ErH2) 159, 160 - - , ground state of 4f-ions in (ErH2) 159, 160 - - , lattice expansion of 70 - - , magnetic ordering temperature of (ErH2)
160 - - , magnetic properties of 175-177 166Er M6ssbauer line
- - in ErH2 and YH 2 159 - - inZrH1. 5 160 EuH x - - , Curie point of 177 - - , electric quadrupole interaction in (EuH2)
160 - - , isomer shifts of 151Eu MSssbauer line in
(EuH2) 160 - - , magnetic properties of (EuH1.86) 177, 180 lSlEu Mtissbauer line
- - in EuNisHx, EuMg2H x 161 - - in EuPdH:,, EuRhzH ~ 160 - - , isomer shifts of, in EuH 2 160 - - , isomer shifts of, in PdHx 152 153Eu Mtissbauer line, isomer shifts of, in
SmH2+ x 160 EuNisHx, a51Eu M6ssbauel: line in 161 EuPdH, , IS~Eu M/Sssbauer line in 160
EuRhzH ~, 151Eu MSssbauer line in 160 Eutectoid decomposition in TaHx 28, 29,37,
51 Evolution of H - - , accelerated, during plastic flow 317 - - in Fe 316 Excess entropies of NbH x and PdH x 96 Excess functions at constant volume 111-113 Excess potential, electronic, of H
in Pd 100, 120 - - in Pd alloys 120, 124, 133, Excess specific heat in PdHx 115 Exchange equilibrium - - between H, D in H 2 0 96 - - between H, D in Pd 91 - - be tweenH, T i n H 2 0 96, 97
between H, T in Pd 94
Fe (~) , absorption and evolution of H in 316
- - , binding energy of H to dislocaicion traps in 318, 319
- - , comparison of H- and muon-diffusion coefficient in 388
- - , diffusion and location of muons in 385- 389, 393, 394
- - , diffusion coefficient of H in 326-329, 342, 343
- - , dipolar fields in 369, 370, 372, 389 , effective charge number Z* of H, D in 292
- - , - - , isotope dependence of 294 - - , Fermi field in 387 - - , Fermi interaction in 386 - - , ferromagnetic polarization of conduction
electrons at muon site in 386, 394 - - , heat of transport Q* of H, D in 298
, , isotope dependence of 299 , -, temperature dependence of 299
H-solubility in single-crystal and poly- crystalline 314, 315
- - , Knight shift of muon spin precession frequency in 386
, Lorentz field in 386, 387 - - , motional narrowing of muon resonance in
386 - - , partial molar volume of solution in 315 - - , quan tum tunneling in 388 - - , solubility of H in 306 - - , transverse relaxation rate in 389 - - , trapping of H by carbides in 315 - - , trapping of H by dislocations in 313,316 - - , trapping of muons in 389 Fe-Al-alloys, trapping of H on surface of
A1N precipitates 315
360 Subject Index
FeH x - - , binding energy of 307 - - , cold-work peak in 317-319
, diffusion aftereffect 306, 307 - - , formation pressure of 176 - - , internal friction in 317-319 - - , magnetic aftereffect relaxation spectrum of
307 - - , Snoek effect in 307, 317-319 5 VFe M6ssbauer line
- - in hydrides o f N i a n d Ni-Fe alloys 147,148 - - i nNbH~ 154 - - in Pdl_yFeyH x 153
- - in RFe2H4(R=rare earth), YFe2H , 155 - - inTi -Fe-H 155 SVFe M6ssbauer line, isomer shifts of
- - in hydrogenated stainless and austenitic steels 155
- - i nNbH~ 154 - - i n N i l_yFeyH x 148 - - in NiH~ 147, 148 - - in Pd l_yFeyB x 130
in Pdl_~,F%Hx 130 - - in PdH x 148
in Pd, _yMyHx (M = Fe, Ag, A1, V) 148 150
- - inTiFeHx 155 - - in various materials 149 FeNi, magnetostatic interactions in 295, 318 FePd, magnetostatic interactions in 295, 318 FeyPd 1 _yH~, D~ - - , activation energy of 313 - - , complex formation in 313 - - , diffusion aftereffect in 313 - - , magnetic aftereffect relaxation spectrum of
313, 314 Fermi (contact) interaction 357, 386, 387 Fermi energy in Pd alloys 118-123 Fermi surface 367 - - , influence of H on 110 Ferromagnetic impurity, H as 295
Ferromagnetic resistance anomaly in NiH~ 187
Ferromagnet ism in 3 d-metals with high H content 193
Ferromagnets 363 - - , depolarization of muons in 356 - - , interaction of muons with dipolar fields in
367 372
FeTi, magnetic aftereffect of H in 289, 293, 295, 300, 314, 318 see also TiFe
FeTiH~ see TiFeH~ FeZr, magnetic aftereffect of H in 295
Fick's diffusion coefficient 146, 275 see also Diffusion coefficient, effective (macroscopic)
Fick's equation 196, 275 Filters, hydrogen 1 Finite jump times 277 Fluctuations in H density 23, 26, 29, 30, 38, 39,
41 Fluidlike diffusion 198, 223, 224 Foamed metals 211 Foils, elastic relaxation (Gorsky effect) in 21,
36, 41-44, 335 Force-dipole tensor see Dipole-moment tensor Formation pressure - - ofCrHx, CrD x 178 - - of FeH~ 176 - - of MnH~ 176, 179 - - of Ni l_yFeyHx, Ni~_yF%D x 175, 176 - - ofNiH~ ,NiD x 173, 174
see also Pressure-composition isotherms and Isotherm(s)
Fracture 1i Free energy of H in metals 22, 27 - - , canonical 23, 29 - - , reference 40 - - , relative partial molar, of PdH x 170 - - , standard, for formation of
, CrH~ 177, 178 - - , - - Nil_~.F%H ~ 176 - - , - - NiH x 160, 173 - - , - - NiH0.s, NiDo. s 173 - - , variational expression for total 23 Free induction decay (FID) 232 Frenkel defect formation 28,29
Fuel cell 1,216
Fugacity - - coefficient 166 - - , equilibrium, of NiHo.s, NiDo.5 173
- - of gaseous hydrogen at high pressures 159, 167, 169, 185, 189
Fusion reactor 1 - - technology 11
gas discharges, supply of active H particles by 158
gaseous hydrogen - - at high pressures 158-161, 165
acting on metals 159 - - acting on steel 16I
- - , chemical potential of 186 - - , destructive action of 161, 162 - - , equation of state of 159 - - , fugacity of 159, 167, 169, 185, 189 - - , PVT data of 159, 187
Subject Index 361
Gd, diffusion and location of muons in 392, 394
GdCo3H2, GdFeaH 2, hysteresis of H absorp- tion in 208
GdCo3H3, magnetic properties of 191 GdCo3H ~ for H storage 223 G d C o s H x for H storage 222,223 GdFe 2 - - , Curie point of 188 - - , magnetic properties of 188 GdFezH~ - - , Curie point of 188
, magnetic properties of 188, 189 GdF% - - , Curie point of 191
, magnetic properties of 191 GdFe3H3, magnetic properties of 191 GdHx
, isomer shifts of 155Gd M6ssbauer line in 160
- - , magnetic hyperfine interactions in 160 - - , magnetic properties of 175-177 Gd0.1La0.9CosHx, 155Gd M6ssbauer line in
161 Gd0.1Lao.gNisH~, 15SGd M6ssbauer line in
161 155Gd M6ssbauer line
- - in Gd0.1Lao.9NisH x and Gd0.1La0.9CosH x 161
- - , isomer shifts of, in GdH 2 160 - - , magnetic hyperfine interactions in GdH 2
studied by 160 GdNi 2, magnetic properties of 191 GdNi2Hx, magnetic properties of 19l GdNisH ~ for H storage 222,223 Geometrical kinks in dislocations 303, 307 Gorsky effect 11, 13, 33, 36, 41-44, 46, 62, 254,
300, 318, 329, 331,333, 334, 341,342, 30, 32, 149, 276, 324
, bending a foil 33, 36, 37, 41-44, 335 - - , bending a wire 36, 37, 41-44, 335 __ determination of c((?l~/ac ) from relaxation
strength of 286 - - , relaxation strength of 32, 33, 41, 43, 44, 46,
335 Grain boundary traps for H 313-315 Gravimetric method for H-diffusion
measurements 324, 335 Green's function - - , elastic 15, 79 - - , static 8 - - , static, of the diffusion problem 35 Gyromagnetic ratio 350 - - of deuteron 351 - - of positive muon 351
- - of positron 351 - - of proton 351
of triton 351
Half width of magnetic aftereffect relaxation spectrum 290
Hall coefficient 177 - - , correlation with effective charge number Z*
296 of CeH~ 177
Hall effect in PdHx, NiH~, Nil_yCuyH x 193 Hall field electrotransport of T in Ti and Zr
296 Hard core 25
- - repulsion 23, 30, 40 Harmonic approximation 7, 8, 10 Harmonic (one phonon) approximation 77 Harmonic oscillator 310, 311
- - model 309 Heat capacity - - anomaly, in PdH x 185
- - measurements at low temperatures 179 - - o f C r H x 177
see also Specific heat Heat of transport Q*
- - , electronic contribution to 283 - - , intrinsic 284
, , o f H , D i n N b 300 - - , isotope dependence of, of hydrogen in
Zi rca lo~2, Fe, Ni, Nb 299 - - o fH, D i n Fe 298
of H, D in Nb 298 - - o fH , D i n N i 298 - - of H, D in Zircaloy-2 298 - - of H i n P d 298 - - of H i n T i 297 - - of H i n V 298 - - of H i n Z r 297 - - , phonon scattering contribution to 283,
284
, temperature dependence of, of H, D in Zr, Fe, Ni, Nb 299, 300
/
Heat storage by hydrides 237
Heat transfer in hydride reservoirs 235 Heat transformer - - , LaNi5H~, MgzNiH:, used in 5, 6
, metal hydrides as 2-9 He backscattering (from NbH~) 30
HfH x - - for H storage 224 - - , magnetic susceptibility of (HfH2) 170 - - , N M R relaxation times in 247 HfV2, HfV2H, HfV2D, superconductivity in
246
362 Subject Index
H - H complex(es) - - , binding energy of, in Nb 321 - - , binding energy of, in Pd 89, 93, 102 - - , concentration of two types of, as function
of binding energy 323 High H-pressure device(s)
- - applying liquid transmitting media 161 163,192, 195
- - for measurements of absorption and de- sorption isotherms 164, 165
- - for thermopower investigations 191 - - for x-ray investigations in situ 162, 163,
194 - - , manostatic, for low-temperature (super-
conductivity) investigations 164, 187 without pressure transmitting media 162-165
High pressure, gaseous hydrogen at 158, 159 HoCo3H~ for H storage 223 HoF% - - , Curie point of 188 - - , magnetic properties of 188, 190 HoFe2H 4 - - , Curie point of 188 - - , magnetic properties of 188-190 HoFe 3 - - , Curie point of 191 - - , magnetic properties of 191 HoFe3H3, magnetic properties of 191
HoH x, magnetic properties of 175-177 HxTaS2, superconductivity in 247 Huang diffuse scattering 58, 59, 64
H~V complex in Nb 325; 326 - - , binding energy of 326
Hybridization of the hydrogen 1 s orbital 174
Hydride engines 236, 237
Hydride formation , enthalpy (standard) for 209
- - , entropy (standard) for 209 - - , hysteresis in 206-209 Hydrides, pressure-temperature-composit ion
(P T-C) relations of 204-206 see also Pressure-composition isotherms
Hydrogen distribution around M6ssbauer a tom 143-145, 148, 163
- - , t97Au, 197Hg, 197pt in PdH:, 151, 152 ,5VCo, STFe in NiH x 148
- - , STCo, 5VFe in PdH~ 150 - - , 166Er in ZrH1. 5 160 - - , 237Np in NpH2+:, 161 Hydrogen gas - - at high pressures 158-161, 165
- - - - acting on metals 159 - - , chemical potential of 186
- - density of 216 - - , destructive action of 161, 162 - - , equation of state of 159 - - , fugacity of 159, 185 - - , PVT data of 159, 187 Hydrogen, methods for storage of 202,203 Hydrogen technology 1 Hydrogen transfer catalysis 134 Hydrogen transfer catalyst 78 Hydrogenation - - , rate determining step of 136 - - , rate of i35 Hydrostatic pressure - - , influence of, on electrical resistivity 181 - - , influence of, on superconducting transition
temperature in PdH~ 188 - - , influence of, on thermopower in NiH x 190 Hyperfine interaction(s) 131, 363, 373, 374 Hypostoichiometry in VDx 23 Hysteresis - - effects at phase transitions 26, 40, 48, 227
- - in absorption or desorption isotherms of PdH~ 167
- - in formation and decomposition of - - - - GdCoaH x, GdFe3H x 208 - - - - LaNisH ~ 208 - - - - Nil_rCorHx, N i l - y CoyDx 176 - - - - Ni0.gCUo.lH x 174, I75 - - - - NiHx 174 - - - - Ni 1 yMn~,H x 181 - - - - TiFeH:, 225 - - - - U l_yNbrH x 208 - - - - VH~ 207, 208,228 - - in hydride formation 206-209 - - in thermopower of Nil_yCu~.H ~ 191
Ideal solution behavior 75 Image displacements 17 Implantation 249 - - of H i n P d 249 - - , supply of active H particles by 158 Impurities 55 - - , analysis of content of 57, 58 Impurity interstitial atom(s) 274, 290, 318 Impurity trapping of H 319-326 Incoherent phase diagram 26, 33 Incoherent phase separation 26, 48, 33 Incoherent precipitates in TaH~ 52 Incoherent states 13, 18, 26, 28, 40, 48 Induction period 213 Influence of stresses on dissolved H 276, 277 Inhomogeneous distribution of protons 14 Inhomogeneous phase 25, 40, 47, 48 Initial susceptibility 290 Intensity form factor 273
Interaction - - , attractive 17 - - , elastic 6 23, 26, 39, 53, 324 - - , elastic, long-range, in domain walls 293
295 , elastic, range of 20
- - , electron-phonon, in PdH~, PdD~ 90,91, 129
- - , exchange 293 , long-range 299, 109
- - , magnetic dipolar 293 --~ magnetostatic 295~ 296
, short-range 293,296 299 , solute-solute, in PdHx 98 i04
Interaction energy of H with domain walls 289, 292 295, 298
Interfaces between precipitates and metal lattice, hydrogen absorption at 315
Interference contrast 29, 44 lntermetallic compound 210, 211 Internal friction
, change of, by phase transitions 30 - - due to H-H and O - H complexes in Nb
320-322 - - - - , orientation dependence of 321, 322
in Felix 317-319 Internal friction measurements on Nb H, D,
and Ta H 331 Interstices see also Octahedral, tetrahedral
interstitial sites , octahedral 366, 380, 381, 386, 390, 392,
393 - - , tetrahedral 366, 380, 381, 386, 390, 392,
393 Insterstitial alloy i1 Interstitial impurities see Impurity interstitial
atoms Interstitial lattice, non-Bravais 271 Interstitial location - - by nuclear microanalysis 326, 327
determination by channeling 327 Interstitial sites 6, 355, 11, 65
, geometry of 268, 271 - - , octahedral 300, 305 - - , tetrahedral 300, 301,305 Intrinsic diffusion coefficient see Diffusion
coefficient, effective Inverse isotope effect see Isotope effect Ion implantation 13, 55 Ir, solubility of H in 306 193Ir M/Sssbauer line, isomer shifts of, in PdH x
151 IR reflection-absorption spectroscopy on PdHu
97, 98 Irreversible transport processes 274
Subject Index 363
Isochromat spectroscopy 132 Isochronal relaxation curves (magnetic) 290,
291 Isomer shifts 131, 139-141, 148-152, 155-157,
161,163 - - of 161Dy M6ssbauer line in DyH 2 160 - - o f lSlEu M6ssbauer line in EuH 2 160 - - of ~SlEu M6ssbauer line in PdH x 152 - - of lS3Eu M6ssbauer line in SmHz+ x 160 - - of 57Fe M~Sssbauer line in hydrogenated
stainless and austenitic steel 155 - - of 57Fe M6ssbauer line in NbHx 154, 155 - - of SVFeM/SssbauerlineinNi~_~,FeyHx 148 - - of SVFe M6ssbauer line in NiH., 147, 148 - - of SVFeM/SssbauerlineinPdi_.FerBx 130 - - of S7Fe M6ssbauer line in Pd 1 _yFeyH x
130 - - of STFe M6ssbauer line in PdHx 148-150 - - of 5VFe M6ssbauer line in Pdl_yMvH x
(M=Fe , Ag, A1, V) 148 150 - - of 57Fe M/Sssbauer line in TiFeH x 155
- - of ~55Gd M6ssbauer line in GdH: 160 - - of 155Gd M6ssbauer line in (Gdo.~La0.9)
NisH x and (Gd0.1La0.9)CosH ~ 161 - - of 237Np M6ssbauer line in NpHa+ x 161 - - of 99Ru, 193Ir, ~95pt, 19VAu M6ssbauer lines
in PdH~ 150-152
- - of 119Sn M/Sssbauer line in PdH x 152
- - of 18aTa MiSssbauer line in TaHx 155 157 Isomorphism of phases of VH x and VD~. 25
Isosteric heat of sorption of PdH~ 160
Isothermal relaxation curves (magnetic) 290, 291,304
Isotherm(s) - - , absorption and desorption, at high pressures - - - - of Ni0.9Cu0.1H:~ 174, 175 - - o fNiH x 173,174 - - , - - of PdHx 167, I68
high H-pressure measuring device for ab- sorption and desorption 164, 165
- - of PdH x at supercriticai temperatures 160 - - pressure-composition - - ofLaNi sHx 222 - - - - of MgaA13H., 219 - - - - of NbH~ 62 - - - - of(Pd alloys) H~ 118 - - - - of PdHx 78, 80, 81, 85, i18, 160, 167,
168, 206 - - of TaH~ 63 - - , - - ofTiCr2H ~" 227, 228 - - of TiFeHx 207, 224, 225, 227 - - , ofTi I _yF%H x 226 - - of TiFeo.9Nio.iH x 227 - - of VH:, 63,208
364 Subject Index
Isotope effect(s) !97, 201, 206, 212, 217, 219, 221, 222, 262, 292, 309-312, 314, 318
- - between dissolved and chemisorbed H in Pd 97, 98
- - b e t w e e n liquid water and PdHx, PdDx, PdT x 96, 97
- - , electronic contribution to, in PdH~, PdD x 9O
- - , equilibrium, in PdH x 88-98 - - in effective charge number Z* 294 - - in heat of transport Q* 299 - - in superconducting transition temperatures
245 - - in superconductivity of PdHx 188 - - , inverse, in PdH~ 89 - - , reversed, in H-diffusion 212, 221,222, 340,
139, 140 see also Diffusion coefficient Itinerant electrons 357, 366, 367
Kanzaki forces 10, 54, 60, 201,205, 212 KHx 217 - - , dissociation pressure of 205 - - for H storage 217 Kinematic depolarization 354, 358 Kinetic(s) - - , hydrogen-metal reaction 212-215 - - - - of Na 213 - - - - of ThzA1 213 - - - - o f U , Th, Ti, Zr 214
of decomposition o f N i H x 160 - - of formation of NiH~ 196 - - - - during electrochemical process 196 - - of phase changes, influence of trapping on
325 Kink - - , dislocation 303 - - , double 303 - - , geometrical 303 Knight shift - - of muon spin precession 366, 386, 394 - - - - in ferromagnetic and nonferromagnetic
materials 367 - - of N M R resonance 258-261 - - - - in VH~, Nbt-Ix, TaH~ 260
-, partitioned model for 258 Kondo effect in Pdo.998Feo.oozIt~ 181 KzReH 9 for H storage 217 K2TcH 9 for H storage 217
(La, Ce)NisH ~ for H storage 222, 223 Lacher 's theory 168 LaCO 5 - - , effect of degassing on lattice parameter of
183
- - , magnetic moment of Co in deuterides of 187
- - , magnetization of/~ and 7 hydrides of 187 LaCosH x for H storage 222, 223 LaCu4Ni, hydriding of, in H-containing gas
mixtures 224 LaH x - - , electrical conductivity of (LaH3) 175 - - , enthalpy and entropy of formation of(LaH2)
209 - - , Knight shift of 259 - - , ~ e narrowing, quadrupole interactions in
242 , linewidth of proton N M R in 231
- - , magnetic susceptibility of(LaH3) 170, 171 - - , NMR-second-moment measurements on
231 , occupancy of octahedral and tetrahedral
sites in 231 - - , superconductivity in (LaHI.96, LaHz.4)
246 - - , T ~ i n 259 La0.sMo.2Ni 5 ( M = E r , Y, Gd, Nd, Th, Zr) for
H storage 222, 223 LaNi s
as electrodes in batteries 236 - - , H solubility in 182, 185 - - , hydride formation for H storage in 211,
212, 214 - - , hydriding of, in H-containing gas mixtures
223,224 La-Ni alloy hydrides for H storage 223 LaNi~ H~ - - , enthalpy and entropy of formation of
(LaNisH6) 209 for H storage 211,212,214
- - , H density in (LaNisH6.7) 216 - - , hysteresis in H absorption in 208 - - in hydride refrigerators 236, 237 - - , inhibition of H desorption in, by sulfur
dioxide 213 , pressure-composition isotherms 222,223
- - used for absorption heat pump 4 used in heat transformation 5 ,6
LaNi4M (M = Pd, Ag, Cu, Fe, Cr, Co), hydrides of.. for H storage 222, 223
(La, Th) NisH x for H storage 222,223 Lattice activated diffusion proeess(es) 214, 215 Lattice distortions 54, 55 Lattice dynamics of meta l -H systems studied
by - - MOssbauer spectroscopy 146 - - neutron scattering 75 100 Lattice expansion 64-72 - - of ErH:, 70
Subject Index 365
- - of LuH~,LuDx 70 - - of NbH:,, NbD x 64-66 - - of NiH~ 70,71 - - of N i - M n alloys 72 - - of Pd I_yAgy 266 - - of Pdo.9Ago.lH x, Pdo.9Ago.iD~ 70, 71 - - of PdH~, PdD~ 69 71, 77, 78 - - of some fcc metals and alloys (Pd, Ni, Ir-Pd,
Au-Pd , Pt-Pd, Ag-Pd, Cu-Pd , Cu-Ni) 71 - - ofTaH~, TaD~ 66, 67
, isotope dependence of 66, 67 - - of TmH~ 70 - - of VH~, VD~ 67-69 - - o f Y H ~ 70 - - used for determination of H concentration
I94 see also Lattice parameter
Lattice forces 7
Lattice gas 99, 274
Lattice model 6 Lattice parameter - - , change of 54, 55, 57, 58, 64 - - , change of, in NbH~, 47-49 - - determination 194 - - , l o c a l 39, 47 49 - - o f N b H 2 18 - - ofNi l_yCuy , Ni 1 rCuyH~ 175 - - , precision measurements of 14 - - , relative change of, in Pdo.sRho. 5 H~, as
function of H pressure 195 see also Lattice expansion
Lattice potential energy 6 Lattice reconstruction 180 Lattice strain energy for PdH~ 108 I l I
Lattice structure - - of CrH~ 124 - - of NbH~, NbD~ 15-i8 - - of PdH~ 106, 107, 77, 78 - - ofTaHx, TaD~ 18-2i - - of TiH~ 112-114
of Till2 113 - - ofTix rVH~ 113 - - of VD~ 23-26 - - of VHx 120 ,21~3 Leakage in high H-pressure devices 161 Length change 56 - - of Pd0.gA0.1Hx 56
see also Lattice expansion L e p t o n s 350 LiA1, reaction of, with H 217 LiA1H 4, H density in 216 LiBaH 3 for H storage 217 LizBeH ¢ for H storage 217 Li3CdH, Li3CdH 3 for H storage 217 LiEuH a for H storage 217
Life time 352 - - of band states 208 - - ofpions 354 - - of positive muon 349, 351,360 - - of positron 351 - - of triton 351 LiH x 217
alloyed with Rh, It, Pd and Pt, for H storage 217
- - , enthalpy and entropy of formation of (LiH) 209
, H density in (LiH) 216 - - , hydrolysis of 203,204 - - , pressure-induced transformation in 157 Line narrowing experiments, dipolar inter-
actions 239-241 - - on/~NbH:, 240, 241 - - on PdHo.63 240 - - onTario.66 240 - - onT hH3 , s 240 - - on TiH:, 240 - - on UH2 240 Line narrowing, quadrupole interactions 241,
242 - - in NbDx, TaD~, VD x 241 - - i n N b H x 241 - - in PdD~ 241 - - of host metal nuclei in VHx, NbHx, LaH~,
242 Line shape function g(~o) 230 Linear response approximation 33 Liquid hydrogen, density of 216 Li4RhH ,, Li4RhH s for H storage 217 LiSrH 3 for H storage 217
Load leveling in electric utilities 201,230-233
Local magnetic fields 365
Localization of proton 204, 207
Localized modes (localized vibrations, local modes) 76, 87, 202, 216, 219-221, 292, 322 see also Optical modes
- - in NbH x 330 - - in PdH~ 325 - - in PdH~, PdD x as function of H, D concen-
tration 264
in T a H , 331 - - in VH~ 334
Longitudinal relaxation rate, conduction electron component Tie of 258, 259
- - , partitioned model for 258
Longitudinal relaxation time (T1) 243-250 - - in ScH1.7, Till1.55 , TIT1.5 245, 257 - - in Tills , ZrHx, HfHx, PdH~, NbHx 247,
248 Longitudinal sound velocities 95
366 Subject Index
Longitudinal spin polarization 356, 362 Lorentz field 357, 368, 372, 386, 387
Lorentz sphere 368, 369
Low-density expansion of free energy 25, 40 Low-temperature phases of TaD x 20
LuH~, LuD~, lattice expansion of 70
Macroscopic dimensions, changes of 55, 56
Macroscopic modes see Elastic modes
Magnetic aftereffect 289-318, 324, 326 Magnetic aftereffect relaxation spectrum
290-292 - - of C-H, C - D complexes in Ni 307-312
of CoHx, CoD x 304-306 - - of FeH~ 306, 307 - - o f (FePd alloys) H~, D~ 313, 314 - - of M-H, M - D complexes in fcc alloys
313-315 - - of (NiFe alloys) H~ 312, 313
of NiH~, NiD~ 303-305 - - of T i -H complexes in Fe 314-318 Magnetic dipole-dipole interaction 228, 293 Magnetic hole 295 Magnetic hyperfine field 131, 142, 152-154,
159-161 - - in ErH2 studied by 166Er M6ssbauer
resonance 160 - - in EuH 2 studied by 1.51Eu M/Sssbauer
resonance 160 - - i n EuPdH~, EuRh2Hx studied by 151Eu
M/Sssbauer resonance 160, 161 - - in GdH 2 studied by 155Gd M/Sssbauer
resonance 160 - - in PdFeH studied by SVFe MiSssbauer
resonance 152-154 Magnetic hyperfine interactions 131,143-146,
152-154, 159-162 Magnetic measurements at high H pressures
192 194 Magnetic moment 350, 355
- - of deuteron 351 - - of NiH~ 192, 193
of positive muon 351 - - of positron 351 - - of proton 351
of triton 351 Magnetic ordering - - in d-metal hydrides 197
- - in rare earth dihydrides 176, 177 - - , suppression of 176 Magnetic ordering temperatures see also Curie
point - - in ErH2 160 - - i n F e P d H 153
Magnetic properties - - o fCeCo 2 186 - - of Cel l 3 175
of CrHx 124, 126, 170 - - of GdCo3H~ 191 - - of GdNi 2, GdNi2Hx 191 - - o fLaCos , LaCosHx 187 - - of LaH3 170, 171 - - o f M n H x 125, 126 - - of NbH0.86 121, 170 - - of NdCo 2, NdCo2H:, 183, 184~ 186, 187,
193 - - of Ni-Fe alloys 147, 148 - - of Pd-Fe H alloys 142, 150, 152 154 - - of PdHx 107, 111, 171, 172 - - of PrBi 186 - - of PrCo 2, PrCozHx 183-187, 193 - - of PrCos, PrCosD~ 188 - - ofPrNi 2 186 - - of ra reea r ths 176 - - of rare earth hydrides 142, 160, 163, 175-
181 - - of RFez (R=ra re earth) 188 190
of R F % H 4 ( R = rare earth) 155, 188-190 - - of R F % ( R = rare earth) 191 - - of R F % H 3 ( R = r a r e earth) 190, 191
of ScH:, 170 o fS mCo 5 182, 183
- - of SmCosH~ 169 - - of TaH~ 121, 170 - - ofThTFe3H x 193 - - ofTh6Mn23 ,Th6Mn23H~ 191, 192 - - of Till:, 114, 119, 170, 171 - - ofTil_yVyH . 114, 115, 174 - - of UH:, 121, 181,182 - - of VHx 119, 121, 123, 170, 171 - - o fYCo 2 186 - - ofYH2. 8 170
- - ofY6Mn23, Y6Mn23H~ 191, 192 - - o f Z r H 2 170 Magnetic susceptibility 103, 104, 127, 298
see also Magnetic properties - - change of, by phase transitions 31
contribution of iron local moments and electron band contribution to, in Pdl -yF%H~ 128, 129
, initial 290 - - isotherms of PdHx 79, 80
of Cr 125 - - of CrH:, 124-126, 170 - - of HfH~ 170 - - of LaHx 170, 171 - - o f M n H x 125 - - of NbH~ 121,170, 32 - - of N i -Pd -P t , R h - P d - A g alloys 254
Subject Index 367
- - of Pd 1ll - - of Pd 1 yAgy 128, 129 - - of PdB x 128, 129 - - of PdD x 128, 129, 251, 252, 266 - - ofPdH x 107, 111,171, 79-81, 128,129, 251,
252, 266 - - of Pd-noble metal alloys 266
- - of PrH x 179 - - of ScH x 170 - - of Tall:, 121, 170, 35 - - of Ti 119
- - ofTiH x 114, 119, 170, 171 - - ofTil_yVrH x 114, 115, 174
- - of V 123 - - ofV0.TCro. 3 171 - - of VHx 119, 123, 170, 171 - - of YH~ 170 - - of ZrHx 170 Magnetization, decrease of, in NiH~,
Nil_yFeyH ~ 192 Magnetocrystalline energy 297 Magnetostatic interaction of H with domain
walls 293-298 Magnetostriction 294 Magnetostrictive strains 293 Manostatic device for low-temperature (super-
conductivity) investigations 164, 187 Mass spectrometry 57, 65 - - on CrH~ 178 Matthiessen's rule 183 Maxwell construction 25-27 Mean-field approximation 24, 323 Mean jump distance 326, 337 Mean partial molar volume 55 Mean residence time 239, 247
see also Mean time-of-stay - - ofmuons 364 Mean time-of-stay see also Mean residence
time - - of H, D in Nb (fl phase) 337, 341 - - o fH, D i n T a 332 - - o fH, D i n V 333 - - of H, D, T in Nb(c~ phase) 330 - - of H i n P d 325, 326 Mechanical relaxation 60
see also Gorsky effect, Snoek effect Mechanical relaxation due to dislocation-
interstitial atom interactions 301-303 Mechanical relaxation methods for diffusion
measurements 324 see also Gorsky effect, Snoek effect
Me-H, Me-D complexes, diatomic - - , activation energies and preexponential
factors for 315 - - in NiCu 314
- - in NiMe alloys 314 - - , isotope effects of 314 Meson - - factories 354 - - , g see Muon - - , x see Pion Mesotrons 349 Metastable configuration 26 Metallic hydrogen 157, 243 Metallography 17 - - on NbH~ 32, 43-49 - - on Tall x 35, 50-52 - - o n V H x 53, 54 Mg, sticking probability of H on 213 Mg alloys, hydrides of, for H storage 220 Mg3AgH x for H storage 220 MgsAl~ hydrides of, for H storage 219 Mg2A13Hx, pressure-composition isotherms of
219 MgAuHx for H storage 220
MglvBa2H.~ for H storage 220
MgCeHx, MggCeH~ for H storage 220
Mg3CdH x for H storage 220 MgzCu -- , hydrides of, for H storage 211, 218, 219
, , dissociation pressure for 205
Mg2Cu0.sNio.sHx for H storage 220
MgH~ -- , dissociation pressure of 205
- - , enthalpy and entropy of formation of
(MgH2) 209 - - for H storage 218 - - , H density in (MgH2) 216 - - , use of MgI 2 catalyst in synthesis of 215 - - used for automotive propulsion 234
Mg2NiHx -- , dissociation pressure of 205 - - , enthalpy and entropy of formation of
(Mg~NiH4.2) 209 - - for H storage 218,219 - - , H density in (Mg2NiHJ 216 - - used for absorption heat pump 4 - - used for automotive propulsion (Mg2NiH4)
234 - - used in Clausius-Rankine cycle 7, 8 - - used in heat transformation 5,6
Mg3Sb2H ~ for H storage 220 MgSnH~. for H storage 220 MgZnH, for H storage 220 Micromagnetism 292 Mischmetal alloys, hydrides of, for H storage
223 Mischmetal pentanickel for remote generation
of electricity 230
368 Subject Index
Miscibility gap - - in Ni l_rCuyH~ 181 - - in Ni l_yMn~,H x i79, 181 Misfit energy 109, ilO MnH~
at high H pressure 179, 180 - - , electronic density of states of 125 -- , electronic specific heat of 125 - - , formation pressure of 176, I79
, hexagonal phase of 179 - - , kinetic barriers due surface contamination
in 179 - - , magnetic susceptibility of 125 Mo, influence of dissolved H on super-
conductivity in 246 Mobility of H 34, 322, 323, 275 - - , concentration dependence due to blocking
of 323 - - , electric 275 - - in Pd 287 Moderator, metal hydrides as, in nuclear
reactors I Modes, elastic see Elastic modes Modulation field, correction for 232 Molecular H i66 - - , molar chemical potential of t66 .. Monocrystalline foils 58 Mono-domain crystal 48,52 Monotectoid point in TaH~ 37 Morphological description of phases 47 Morphologies of phases 41-54 - - of NbH, 43-51
, studied by electron microscope 49-51 , studied by metallography 43--49
- - of TaH~ 50-52 , studied by electron microscope 52
- - - - , studied by metallography 50-52 - - of VH~ 53, 54 - - - - , studied by electron microscope 52 - - - - , studied by metallography 53, 54 MtSssbauer spectroscopy
, compilation of M - H systems studied by 164
- - , diffusion of H measured by 145, 146, 157- 159, 322, 331
- - , experimental techniques for 138, 139 - - , 57Fe hyperfine field in Pd~ y_zAg~Fe
studied by 153 - - , 57Fe hyperfine field in Pdo.gs yAnyFeo.o2
studied by 153, 154 - - , 57Fe hyperfine field in Pdl _~FeyH~ studied
by 152-154 - - , isomer shifts in see Isomer shifts - - , isotopes for the study of M-H systems by
133, 137, 138
-- , motional narrowing of 181Ta M6ssbauer lines due to H diffusion 157-159 on 16°Dy, 166Er in YH 2 159 on 166Er in YH 2 159
- - on 166Er in ZrH1. 5 160 - - on ~51Eu in EuNisHx, EuMgzH ~ 161
- - on ~51Eu in EuPdHx, EuRh2H ~ 160 - - on a53Euin SmHx 160
on 151Eu, 171Yb in EuHa, YbH 2 160 - - on S7Fe in hydrogenated stainless and
austenitic steels 155 on 5VFe in NbH x 154, 155
- - on 57Fe in Ni 1 rFerH x 147, 148 - - on STFein NiH x 147 - - on 57Fe in Pd l_yFeyB~ 130 - - on 57Fe in Pd l_rF%,Hx 130 - - on 57Fe in TiFeH~ 155 - - on 57Fe in VH, 155 - - on 57Fe in YFe2Hx, GdFezH x 155, 190 - - on 155Gd, 161Dy in GdHx, DyH~ 160
- - on iSSGd in (Gdo.lLao.9)CosH ~ 161 - - on 155Gd in (Gdo.lLao,9)NisH~ 161 - - on Z37Np in NpH2+ ~ 161, 162 - - on *41Pr in PrNisH x 161 - - on *S~Tain Ta l l , 155 - - , resonance lines for the study of M - H
systems by 133, 137, 138 Motional narrowing 228, 239-242
see also Line narrowing - - of muon resonance 364, 380, 384, 386 - - of lS~Ta M/Sssbauer line due to motion of
H in TaH~ 145, 146, 157-159, 324 Multiphonon processes 78 Multipole expansion 16 Multisite occupation 277 Muon(s), positive 305, 349
- - channels 354 - - ,decay reaction of 352 - - , diffusion and location of 374-394
, in c~-Fe 385-389, 393, 394 , in A1, Bi, Cr, fl-PdHo.97 384, 385, 394 , in Co 391-394
- - - - in Cr 385, 392-394 , in Cu 374-379, 393, 394 , i nGd 392, 394
- - , - - in group V transition metals 379-384, 393, 394
-- , - - in Ni 390, 393, 394 ~ , diffusion coefficient of, in Cu, comparison
with theory 213 - - , gyromagnetic ratio of 351 - - , life time of 349, 351, 360 - - location 355-357 - - , magnetic moment of 351 -- ,polarization of 353-355
Subject Index 369
- - production 354, 355 - - production facilities 354 - - , residual polarization of 358 - - , rest mass of 351 - - , spin of 351
- - spin relaxation in ferromagnets 371 - - spin rotation (IaSR) 355-360
, relaxation functions of 361,362 , relaxation times of 361,362 , telescope 360
- - trapping 365, 372, 380, 382, 384, 389, 393 - - , wave function of 366
, , finite extension of 379 Muonium 351,355, 373, 374 - - , formation of 356, 372-374, 393 - - , precession frequency in A1, Cu, Zn, C
(graphite) of 374
Na, hydriding kinetics of 213 NaA1H 4 for H storage 221 Na2BeH, , for H storage 217 NaHx 217 - - , enthalpy and entropy of formation of (Nai l )
209 - - , H density in (Nail) 216 Nb - - , binding energy of H-V complex in 325,
326 - - , binding energy of N H , O-H, O - D and
H - H complex in 320,32i - - , comparison between H- and muon-diffusion
coefficient in 383 - - , diffusion and location of muons in 379-
384, 393,394 - - , diffusion coefficient of D in 329, 330
, , comparison with theory 212-2141 222 , , concentration dependence of 335
diffusion coefficient of H in 47, 252, 280, ' 281, 329, 330 , , activation energy of 240, 241, 256, 329 ' 22 "c°mparis°nz with theory 212-214, 217,
, concentration dependence of 335-337 , , concentration dependence of activation
energy of 255, 256, 336 , , determined by QNS 280, 281 , , direct measurement by N M R pulsed
gradient method 252-254 , , i n presence of N impurities 267, 283-
285 , i so tope dependence of 329, 330, 339
,33~shape~ dependence of 46, 47, 324, 334,
- - , diffusion coefficient of T in 330 - - , effective charge number Z* of H, D in 292
, concentration dependence of 295, 296 , isotope dependence of 294
, , temperature dependence of 294, 295 ~ , geometry of O - H complex in 322, 323 - - , heat of transport Q* of H, D in 298
, comparison with diffusion coefficient 299, 300
, , intringic 300 , , isotope dependence of 299 , , temperature dependence of 299, 300
identification of H-diffusion mechanism in 250
- - , influence of dissolved gases on super- conductivity in 246
- - , internal friction due to H - H and O - H complexes in 320, 322
- - , mean time-of-stay of H, D, T in 330 - - , orientation dependence of O - H internal
friction peak in 322 - - , quadrupole effects in 381 - - , step length for H diffusion in 257 - - , trapping of H in, by O or N impurities 320,
32i - - , trapping o f m u o n s in 382 NbD~ - - , acoustical phonons in 93 - - , cw absorption curves (NMR) in 237, 238 - - , diffuse neutron scattering on 60, 61 - - , elastic constants of 91 - - , lattice expansion of 64-66 - - , lattice structure of i5~i8 - - , line narrowing, quadrupole interactions in
241,242 - - , optical modes (localized mode) in 79 85,
330 - - , phonon density of states of 95 - - , phonon dispersion curves of 83, 93-95 - - , quadrupole interaction in 236, 237, 239 - - , spinodal temperatures of bulk modes
determined by small-angle neutron scattering on 44, 45
Nbo.78Geo.22, Nbo.vsGeo.2~H x, super- conductivity in 246
NbH x - - , axial asymmetry parameter (NMR) of 237 - - , calorimetry on 32 - - C P M G pulse technique (NMR) on 253 - - , deviations from stoichiometry (fl phase) of
34 - - , y diffractometry on 32 - - , diffuse x-ray scattering intensity of 59 - - , dissociation pressure of 205
, DTA on 32 - - , elastic constants of 91 - - , electrical resistivity of 28, 29, 32
370 Subject Index
NbHx (continued) - - , excess entropies of 96 - - for H storage 228 - - , Gorsky effect on 32 - - , He backscattering from 30 - - , hydride morphologies in 43-51
, , electron microscope results 49-51 , -, metallographic results 43-49
- - , isomer shifts of 57Fe M/Sssbauer line in 154, 155
- - , Knight shift in 259, 260 - - , lattice expansion of 64-66 - - , lattice structure of 15-18 - - , line narrowing, quadrupole interactions in
241,242 , local lattice parameter in 47-49
- - , magnetic susceptibility of 121, 170, 32 - - , metallography on 32 - - , M6ssbauer effect on 32
, neutron diffi'action on 32 - - , NMR on 32 - - , NMR relaxation times in 247, 248 - - , nonstoichiometric (fi phase) 34 - - , optical microscopy on 32, 43~t8 - - , optical modes (localized modes) in 79-85,
330 - - , phase diagram of 40, 41, 135, 155, 31-34 - - - - , schematic 12
, theoretical 40 - - , phases of 154, 155 - - , 6 phase precipitation in fi phase of 43 - - , pressure-composition isotherms of 62 - - , quasielasticintensity of 281-283 - - , quasielasticneutron scattering on 277-285
-, quasielastic width 277-281 - - , relative lattice parameter change of 65 - - , relative volume change of 66 - - , relaxation strength of the Gorsky effect in
(wire and foil samples) 43, 44 - - , superconductivity in (NbH2) 246 - - ,TI~ of 259, 260 - - , transmission electron microscopy on
15-18, 32, 49-51 - - , x-ray diffraction on (NbHo.83) 28 - - x-ray lattice parameter measurements on
32 - - , x-ray spectroscopy on 121
- - x-ray structure analysis on 32 Nb-Pd, Nb-Pd Mo, Nb P d W , Nb-Rh,
Nb-Ru alloys, effect of H on superconduc- tivity of 247
Nb3SnHx, superconductivity in (Nb3SnHo.5) 246
NdCo 2 - - , Curie point of 186
- - , effect of H on 183, 184, 186, 193 - - , magnetic properties of 184, 186 NdCozH ~ - - .Cur ie point of 185 - - , magnetic properties of 187 NdCosH ~ for H storage 222, 223 NdH~ -- , Curie point of 177 - - , magnetic properties of 175-177 NdNiz, Curie point of 186 NdNis, H solubility in 185 NdNisH x for H storage 222,223 Nearest neighbor effects in Pd alloys 118 123 Nearest neighbor interaction I23 Neutrinos 350 Neutron diffraction 14 - - o n N b H x 32, 34 Neutron incoherent scattering function
S~. c(q,co) 268 Neutron radiographic method for H-diffusion
measurements 331 Neutron-scattering cross sections 76
Neutron-scattering experiments - - on PdHx, PdDx, H-charged Pd-Ag alloys
260, 261 - - on ThH z, Th4H25 267 Nit 3, density of H in liquid 216
N - H complex - - , binding energy of, in Nb, Ta 321 - - , reorientation of 213
Ni - - at high H pressures 173, 174 - - , diffusionandlocationsofmuonsin 390,393 - - , diffusion coefficient of D in 338
, , activation energy of 304 - - , diffusion coefficient of H in 326, 327 - - , - - , activation energy of 304, 326
, , comparison with theory 221 , -, isotope dependence of 338, 340
- - , dipolar field in 390 - - , effect of muon on conduction electron spin
density in 394 - - , effective charge number Z* of H, D in 292,
294 -, isotope dependence of 294
- - , heat of transport Q* of H, D in 298, 299 , , isotope dependence of 299 , -, temperature dependence of 299
- - , neutron diffraction data on 390 - - , partial molar volume of solution in 315 - - , solubility of H in 306 - - , solubility of H in polycrystalline 314, 315 - - , spin precession of muons in 390 Ni alloys at high H pressures 174-177
Subject Index 371
NiC 289, 318 Ni l_yCoyH x,Ni 1 ~.CoyD x 176 - - , hysteresis in 176 Nil -rCuyH~ - - , absorption and desorption isotherms of
(Nio.gCuo.~Hx) 174, I75 - - , criticalregion of(Ni0.9Cuo.lHx) 174 - - , Hall effect in 193 - - , hysteresis in (Nio.gCuo.lHx) 174, 175 - - , lattice parameter of, as function of Ni
content 175 - - , miscibility gap in 191 - - , phase separation in 175 - - , thermopower of I91
, , hysteresis in 191 NiDx - - , equilibrium fugacity of (NiDo.5) 173 - - , equilibrium pressure of (NiDo.5) 173 - - , formation pressure of 173 - - , magnetic aftereffect relaxation spectrum of
303-306 - - , standard enthalpy of formation of (NiD0.5)
173 , , isotope effects in 173
- - , standard entropy of formation of (NiDo.s) 173
- - , standard free energy of formation of (NiDo.5) 173
NiFe 289, 293, 300, 318 Ni 1 - yFeyHx -- , binding energy of 312 - - , Curie temperature of 193, 194 - - , decomposition pressure of 176 - - , electrical resistivity of 181, 182 - - , formation pressure from electrical resistiv-
ity measurements i75, 176 - - , free energy of formation of 176 - - , isomer shifts of 57Fe M/Sssbauer line in
147, 148 - - , magnetic aftereffect relaxation spectrum of
312, 313 - - , orientation aftereffects in 312 - - , phase separation in 175 - - , phononic contribution to electrical
resistivity of I82 - - , reduction of magnetization of I92 - - , thermopower of 191, 192 NiH x 158, 160, 177, 197 - - , absorption and desorption isotherms of
173, I74 - - , apparent (macroscopic) diffusion coefficient
of 196 - - , band structure calculations of 187 - - , critical region of 174 - - , critical parameters of 174
- - , Curie temperature of 193, 194 - - , decomposition kinetics of • '160 - - , decomposition of 174 - - , decomposition pressure of 160, 174 - - , decrease of magnetization in 192 - - , direct synthesis from elements of 160 - - , electrical resistance of 174, 187 - - , - - at unidimensionalpressure 187
, electronic heat capacity of 187 - - , equilibrium fugacity of (NiHo.5) 173
, equilibrium pressure of (NiH0.5) 173 - - , ferromagnetic resistance anomaly in 187 - - , formation of, by electrochemical methods
160 - - , formation pressure of 173, 174 - - , free energy of formation of 160
, Hall effect in 193 - - , hysteresis in 174 - - , i somer shifts of 57M6ssbauer line in 147,
148 - - , lattice expansion of 70, 71 - - , magnetic aftereffect relaxation spectrum of
303-306 - - , magnetic moment of 192, 193
, magnetostatic interactions in 295 - - , standard enthalpy of formation of (NiHo.5)
173 , , isotope effects in 173
- - , standard entropy of formation of (NiHo.s) 173
- - , standard free energy of formation of (NiHo.5) 173
, stoichiometry of 173 - - , thermopower of 177, 189-191
Nil_yMyH x (M=Cu, Fe, Mn, Co) 174-177
Ni l_yMnrH ~ 175, 179 - - , decomposition of 181 - - , electrical resistance of, as function of H
pressure 180, 181 - - , formation and decomposition pressure from
resistivity measurements 175 - - , hysteresis in electrical resistance of 181 --, latt ice expansion of 72 - - , miscibility gap in 179, 181 - - , phase separation in 175
Ni Pd alloys at high H pressures, thermal power of 177
Ni -Pd-Pt alloys - - , magnetic susceptibility in 254
- - , solubility of H, D in 253 - - , specific-heat coefficient in 254 - - , superconducting transition temperatures in
H(D) charged, as function of composition of host matrix 253 255
372 Subject Index
Nitrogen impurities, diffusion of H in Nb with 267, 283 285
Nomarski interference 47 Nonequilibrium phenomena 33 Nonequilibrium thermodynamics 274 Nonideal solution behavior of PdHx 108 118 - - , elastic contribution to 76 - - , electronic contribution to 77 Nonlinear mode coupling 38 Non-steady-state technique for diffusion
measurements 143, 144 NpH2+x - - , distribution of hydrogen atoms in 161 - - , isomer shifts of 23VNp M/Sssbauer line in
161 - - , Z37Np M~ssbauer line in 161 - - , quadrupole interaction of 2aTNp
M6ssbauer line in 161 23VNp M/Sssbauer line - - , electric quadrupole interactions in NpH 2 +
studied by 161, 162 - - , isomer shifts of, in NpH2+ ~ 161 Nuclear acoustic resonance 331 Nuclear dipole-dipole interaction 228 Nuclear magnetic moments 365 - - , in te rac t ion o f m u o n s with 357 Nuclear magnetic resonance (NMR) 227-265,.
322, 324, 334, 335, 337, 341 - - and quasielastic neutron scattering 248-
250 - - , axial asymmetry parameter in 234, 239 - - , - - of NbH~, TaH~ 237 - - , background gradients in 251,262 - - , multiple pulse technique (pulsed gradient)
in 252-257, 262 , -, application to NbH~, PdHx 255-257
- - , pulsed gradient technique in (direct measurement of H-diffusion coefficient) 250-257
~, application to VH0.3, NbHx, PdH~, PdyAg 1 _yH~ 252
- - , relaxation rate theory for 243-248 - - relaxation times 243-248 - - - - in ScH1.7, Till1.55, TIT1.5, Til ls , ZrH~,
HfH~, PdD~, NbH~ 247, 248 - - - - , Sholl model for 245-247 - - - - , T o r r e y model for 245, 246 - - - - , Wolf model for 246, 247 - - , spin-lattice (longitudinal) relaxation,
contribution of conduction electrons 259 Nuclear magneton 351 Nuclear microanalysis, interstitial location by
326, 327 Nuclear physics in determination of phase
transitions 30
Nuclear quadrupole splitting, host metal, in VHx, VD x 237
Occupation numbers 6 Octahedral (interstitial) sites 326, 366, 368,
370, 379-381, 386, 390, 392, 393, 18, 21-25, 167, 184, 185, 190, 314, 315
Octahedral-octahedral jumps 270 273, 279, 337
O - D complexes, binding energy of, in V, Nb, Ta 321
O - H complexes - - , binding energy of, in Nb, Ta 321 - - , geometry of 321,322 - - in Nb, magnetic aftereffect of 300, 301 - - , (111) or (100) orientation of 322 - - , orientation dependence of internal friction
peak caused by 322 , reorientation of 213 , trigonal symmetry of 322
One-band model for PdH x 193 Onsager relations 275, 279~81 Optical micrograph 60 Optical microscopy 29, 58 - - on NbH~ 32, 43-48 - - o n T a H ~ 51, 52
on VHx 53, 54 - - , phase transitions shown by 29 Optical modes 79-90, 245 - - , contribution to superconductivity of, in
PdHx, PdD~ 262, 265 - - , frequencies of 81 - - in CeHx, CeDx 90, 97, 98 - - in NbD x 80-83 - - in NbH~ 79-82, 330 - - in Pdl_yAgyH ~ 261
- - in PdDx 81, 85-88 - - in PdHx 81, 85-88, 325 - - in rare earth dihydrides 89, 90 - - i nTaD~ 81, 83, 96 - - i n T a H x 81, 83, 96, 331 - - i n T h H x 89, 90 - - in VD~ 84 - - i n V H x 81, 83, 84, 334 Optical phonon density of states of ThH 2,
Th4Hz5 267, 268 Optical phonon-dispersion curves see Optical
modes Orbital hyperfine fields 258 Order-disorder transformation 34, 47 Orientation aftereffect (magnetic) 294,
299-301,318 - - in CoHx, CoD~ 306 - - in (NiFe alloys) H~ 312, 313 - - in NiHx, NiD~ 304
Subject Index 373
- - of C-H, C D complexes in Ni 307-312 - - of M-H, M D complexes in various fcc
metals 313 315 - - of Ti-H complexes in Fe 316-318 Ortho-positronium 352 Orthorhombic configuration of C-H complex
310 Orthorhombic symmetry of interstitial sites
297 Over-barrier jumps 198, 217, 222 Oxide film - - , effect on hydriding of 212
, removal of, on Zr and Ti 212
Pair interaction energy of H, D in Pd 89, 93, 102 see also Binding energy
Paramagnetic ions 357 Parity non-conservation 352 Partial molar volume 55, 78,166,167, i69,172,
197 Pauli paramagnets 170, 366 Pd
, amplitude of vibration of H, D in 89 as protecting layer i50, 15I
- - at high H-pressures 167-171, I87-19I - - , chemical potential of dissolved H in 74 77 - - , chemisorption of H on surfaces of 85~8
, de Haas-van Alphen effect on 132 , Debye temperature of 260 , diffusion coefficient of D in 338, 340, 145,
149 , , comparison with theory 221 , diffusion coefficient of H in 252, 255, 256,
325, 145, 149 , activation energy from NMR line
narrowing experiments (PdH0.63) 240 , , activation energy of 240, 255, 325, 149 , , comparison between NMR and other
techniques 255, 256 , -, comparison with theory 221, 222 , , direct measurement by NMR pulsed
gradient method 252 , -,isotope dependence of 338, 340
- - , diffusion coefficient o fT in 338, I45 , ,comparison with theory 213. 221
diffusion of H in I34-151, 196, 197 - - , drift-flux measurements of H in 286, 287 - - , effective charge number Z* of H, D in 293 - - , electric diffusion potential measurements on
H i n 289, 290 - - , electric mobility of H in 287 - - , enthalpy of desorption of H from 86 - - , excess potential of H in 120 - - , exchange equilibrium between H, D, T in
94, 95
- - , H-absorption isotherms, effect of deformation on 312, 313
- - , H-solubility in, effect of lattice defects on 312,313
- - , H-solubility in, effect of stress on 312 , H-solubility parameters for 306
- - , heat of transport Q* of H in 298 - - , identification of H-diffusion mechanism in
250 , influence of H loading on isomer shift in
152 - - , isotope effects between dissolved and
chemisorbed H in 97,98 - - , limiting concentration of H in I67
, mean time-of-stay of H in 325 - - , pair interaction energy of H, D in 89 - - , separation factor between H, D,T in 91-98 - - , spin fluctuations in 265
, thermodynamic data of H in 125 Pd black 84, 85 - - , trapping of H in 84, 85 Pd 1 yAgy 106-I08
, diffusion coefficient of H, D, T in 145 , diffusion coefficient of H in, direct
measurement by NMR pulsed gradient method 252
, effective charge number Z* of H, D in 293 - - , electronic specific heat of 129 - - , magnetic susceptibility of 128, 129 - - , miscibility gap of i07 Pd 1 _yAgyDx, superconducting transition
temperature of, as function of Ag concentra- tion 255, 256
Pd0.9Ag0.1D~, lattice expansion of 70, 71 Pdl _yAgyHx - - , electrical resistance of I83-185 - - , lattice expansion of 70, 71
, low temperature resistivity anomaly in 185 - - , optical modes of 261 - - , relative length change of 56 - - , residual resistivity in 185
, superconducting transition temperature of, as function of Ag concentration 255, 256
Pd 1 yAlyHx, superconducting transition tem- perature as function of AI concentration in 256
Pd alloys at high H-pressure 171-173
- - , chemical potential of H in 119 - - , diffusion coefficient of H, D, T in 145 = , diffusion of H in 134-151
, electron-phonon interaction in i33 - - , excess potential of H in I20
, - - , electronic 120, 124, 133 - - , Fermi'energy in 118-123
374 Subject Index
Pd alloys (continued) - - , magnetic susceptibility of 128, 129 - - , nearest neighbor effects in 118-123 - - , pressure-composition isotherms for H in
118 - - , solubility enhancement in 120 - - , statistical thermodynamics of ternary
123-127 - - , strain energy in 120, 124 - - , ternary 118-123 - - , thermodynamic data of H in I25 - - , valence electron concentration in 121 Pd 1 _yAuy - - , absorption of H at high pressure in 171,
I72 - - , diffusion coefficient of H in i45 Pd a _ yAu~,H~ - - , electrical resistance of 183 - - , superconducting transition temperature of,
as function of Au concentration 255,256 PdB x 105, 106 - - , magnetic susceptibility of 128, 129 - - , superconducting transition temperature in
257 PdCx, superconducting transition temperature
in 257 Pd 1 _~.Cuy, diffusion coefficient of T in 145 Pd0.47Cu0.53 (bcc, fcc), diffusion coefficient of
H in 342 pdl_yCuyHx, Pdl_vCuyD~, superconducting
transition temperature in, as function of Cu concentration 255, 256
PdD:, - - , acoustical modes in 260 - - , anharmonic effects in 264 - - , electron-phonon interaction in 90 - - , lattice expansion of 69, 70 - - , line narrowing, quadrupole interactions in
241 - - , localized mode as function of D concentra-
tion in 264 - - , magnetic susceptibility of 128, 129, 251,
252, 266 - - , optical modes of 81, 85-89, 261
, contribution to superconductivity of 262
- - , phonon density of states of, comparison with tunneling experiments 263
- - , phonon dispersion curves of 85, 86 - - , preparation methods for superconducting
187-189, 249, 250 - - - - , H implantation 249, 250 - - , - - , high pressure or electrolytic charging
187-189, 249 - - , quasielastic intensity of 282, 283
- - , superconducting properties of 187-189, 250-257
, superconducting transition temperature of 188,251-253
, , concentration dependence of 25i, 252 , , pressure dependence of I88,252,253
- - , superconductivity in (x > 0.8) 90, 91, 187- 189, 247
- - , tunneling experiments on 261-264 , zero point energy of 89
Pd3Fe , absorption of H in ordered and disordered 172
- - , 7 coefficient of electronic specific heat I72 - - , electronic specific heat of 112
, hydrogen absorption in 112
Pd 1 _~.Fe~.B~ , isomer shifts of STFe M6ssbauer line in I30 , q uadrupole splitting of s 7Fe M/Sssbauer line
in I31
Pd 1 - yFeyHx - - , contribution of iron local moments and
electron band contribution to magnetic sus- ceptibility of 128, i29
- - , isomer shifts of 57Fe M6ssbauer line in 148, 130
, Kondo effect in 181 - - , magnetic properties of 152-154
Pd3FeHx, electrical resistance of ordered and disordered I82, I83
PdHx , absolute thermoelectric power at high H
pressure in I89, 190 - - , absorption and desorption isotherms at
high H-pressures 167, 168 , anharmonic effects in 264
- - , bonding states in 109 - - , cluster formation in 113 - - , contribution of optical modes to super-
conductivity in 262 - - , critical point of 82 - - , Debye temperature of 260, 264
, Debye-Waller factor of 87 , determination of H-concentration in I67 , deviations fi'om Wiedemann-Franz law in
196 , diffusion of muons in (fi-PdH0.9v) 385 , effective {macroscopic} diffusion coeffi-
cient of, as function of H fugacity 196, 197 - - , electrical resistivity of I60, I83
, , anomaly of I85, i87 , temperature dependence of 264, 265
electron-phonon interaction in 90, 91, 129 - - , electronic density of states of 107-i11, 135
Subject Index 375
, electronic specific heat of 107, 108, 111, 259, 260
- - , enthalpy of formation of fi phase 82 , excess entropies of 96
- - , excess specific heat in 115 - - , Fermi surface of 110
- - for H storage 229
, formation of, using catalysts 215
- - , Hall effect in 193 -- , IR reflection-absorption spectroscopy in
97, 98 - - , isomershiftsof*SZEuM6ssbauerlinein 152 - - , isomershiftsofSTFeM6ssbauerlinein 148
, isomer shifts of 99Ru, 193Ir, 195pt, 19VAu
M6ssbauer lines in 150-152 , isomer shifts of 119Sn MSssbauer line in
152 - - , isosteric heats of sorption of 160
, isotherms at supercritical temperatures in 160
- - , isotope effect in , electronic contribution to 90 , equilibrium 88-98
, ,inverse 89 lattice dynamics calculations for 79
- - , lattice expansion of 69-71, 77, 78 --, latt ice strain energy for 108 111
, lattice structure of 106, 107, 77, 78 - - , localized mode as function of H concentra-
tion in 264 - - , magnetic susceptibility isotherms of 79~1
, magnetic susceptibility of 107, 111, 171, 172, 79-81, 128, 129, 251, 252,266
, NMR relaxation times in 247 - - , non-ideal solution behavior of 108-118
, optical (localized) modes in 81, 85-88, 325 , phase diagram of 135, 77~4
- - , phonon density of states of 87 , comparison with tunneling experiments
263 - - ,photoemiss ion of 108
, plateau pressure (dissociation pressure) of two-phase region of 8I, 205
- - , preparation methods for superconducting I87 189, 249, 250
, ,codeposition of Pd and H 250 , , H implantation 249, 250
-, high pressure or electrolytic charging 187-189, 249
,,pressure-composition isotherms of 78, 80, 8I, 85, liB, 160, 167, I68, 206
- - , quasielastic intensity of 282, 283 --,quasielastic neutron scattering (quasi-
elastic width) on, (c~ phase) 275-277
, quasielastic neutron scattering (quasie- lastic width) on, (fl phase) 277
- - , relative partial molar enthalpy of, at high concentrations 170, 171
, relative partial molar entropy of, at high concentrations 170, i71
, relative partial molar free energy of, at high concentrations I70
- - , relative volume change of 69 - - , solubility determination in
, by electrochemical technique 78 - - by UHV technique 79
- - , solubility of H in, at high H pressure 159 - - , solute-solute interactions in 98-104
, specific heat anomaly in 113-118, 185 , statistical thermodynamics of 98-i04,
I68 , stoichiometry of 167, 170
- - , superconducting transition temperature of I88, 251-253 - - , concentration dependence of 251,252
, - - , pressure dependence of 187, 188, 252, 253
, superconductivity in 89, 108, 111, 187- I89, 250-257
, superconductivity in (x >0.8) 90, I67, I85, 187-189, 247 - - , saturated cathodic I87
- - , surface behavior of 84-88 - - , thermal conductivity of 196 - - , f l~ transition enthalpies of 82-84 - - , tunneling experiments on 261-264
, two-phase region of 82 - - , width function of quasielastic neutron
scattering on 271 - - , zero-point energy of 89 Pd like interstitials 172 Pdt_~.My (M = Ag, Au, Cu, Pt)~ absorption of
H at high pressures in 172, 173 Pd 1 _vMyH:, (M = Fe, Ag, A1, V), isomer shifts
of 5VFe MiSssbauer line in 148-150 Pd-N, superconducting transition temperature
in 257 Pd l_yNiy, diffusion coefficient o fT in 145 Pd 1 yPty, reduction of H solubility with
increasing Pt content in 172 Pdl _yPtyHx - - , electrical resistivity in 173 - - , position of electrical resistance maximum in
185, I86 Pd 1 _ yRhyH~.
- - at high H pressure 172 - - , stoichiometryin 172 Pd0.gRh0.1, diffusion coefficient of H in 145 Pd0.sRho.sH:,, lattice parameter of i95
376 Subject Index
PdTx, p phase isotherms of 95 Pdl_yTiyHx, superconducting transition tem-
perature of, as function of Ti concentration 256
Pd l_yV~,, diffusion coefficient o fT in 145 Peierls potential 303 peritectoid reaction in Ta l l x 28, 5I Permeation 137
- - measurements on Pd foil i38 - - , stationary 134-140
, unsteady 142, 143 Permeation methods for H-diffusion measure-
ments 324, 340, 137-140 Phase boundaries, determination of, - - by N M R 227 - - by optical microscopy 29 Phase diagram 26-41
, incoherent 26,33 - - of N b - H 40, 41, 135, 155, 3 1 0 4
- - o f N b H (theoretical) 27, 30, 40, 41 - - of Pd -H 135, 77-84
- - of rare earth hydrides 136, 137 of T a - H 135,35-38
- - of TiFeHx 224,225 - - of(Til_~.V~.) H~ 113
of V-D 40-42 of V-H 38-40
- - of V H, T a - H (theoretical) 30 , schematic
- - of Nb-H , Ta-H, V-H 12 - - - - of V-D 43 Phase-diagram analysis by M6ssbauer
spectroscopy 143, 147, 148, 154 - - in N b H . 154
in Ni l_yF%H . 148 in NiH x 147
Phase morphologies see Morphologies of phases
Phase separation - - , coherent 26, 13,33
, incoherent 26, 33 in Nil_yCuyH~, Nil_yFeyHx, Ni~_yMnyHx 175
Phase transition(s) 24, l l , 157 , change of internal friction by 30
- - , coherent 29 - - in solid hydrides 157 - - , bD-+ YD, in VD~ 25 - - , methods to observe 27-3I - - , order-disorder 27 - - shown by optical microscopy 29 - - , temperature width of 227, 237 Phonon density of states 77, 244
of Nb 95 - - of NbD0.4s 95
- - of PdH 87 - - of PdH0.63 and PdDo.63, comparison with
tunneling experiments of 263 , optical, of ThH2, ThcH25 267,268
Phonon-dispersion curve(s) , influence of dissolved H and D on 75,
9048 , 262, 263 offiNbDo.Ts 83 o f C e D x 97, 98
- - of Nb 93,94 - - o f N b D x 93~95
- - of PdDo.63 85, 86 of TaDx 96, 98 of TaH~ 96
Phonon scattering, temperature dependence of electrical resistivity due to 29
Phononic contribution to electrical resistance in Ni I _~,FeyH:, 182
Photodecomposit ion of H 2 0 193 Photoemission - - of PdH x 108 - - of TiHx 116 Pion (re-meson) 349 - - , life time of 354
- - rest system 354 Plane-stress approximation 21, 36, 42, 47 Plastic deformation at phase transformations
14, 3l Polarization 354, 355 - - , longitudinalspin 356,362
of conduction electrons 370, 386 - - o f m u o n s 353-355 - - , residual, of a muon 358 - - , transverse spin 356, 364, 378 Polarization contrast 29, 44-46, 50, 53, 54 Positron - - , emission probability of 353 - - , gyromagnetic ratio of 351
,life time of 351 - - , magnetic moment of 351
, res t mass of 351 - - , s p i n o f 351 P o s i t r o n i u m 351 Power density of hydrides 233 PrBi, magnetic properties of 186 PrCo 2
,effect of H on 183, 184, 186, 193 - - , magnetic properties of 184, 185 Pr-Co alloy hydrides for H storage 223 PrCo2H~, magnetic properties of 187 PrCos, PrCosD~, magnetic moments of Co in
187, 188 PrCosH x for H storage 222,223 Precession wiggles 374 - - , decay of, in Cu 374, 375
Subject Index 377
Pre-exponential factor 212, 213, 219, 221,291, 307, 309, 315, 317
- - for diffusion coefficient of H, D in Nb 252, 329, 341
, concentration dependence of 336, 337 - - for diffusion coefficient of H, D in Ta 331
, concentration dependence of 336, 337 - - for diffusion coefficient of H, D in V 252,
333 - - for diffusion coefficient of H in Fe 329 - - for diffusion coefficient of H in Ni 326 - - for diffusion coefficient of H, D, T in Pd
252, 255, 325, 145, 149 - - for diffusion coefficient of H, D, T in
Pd~_yAgy 145 - - for diffusion coefficient of H in
Pdo.ssAuo.4s, Pdo.9Rho. 1 145 - - for diffusion coefficient of muons in Cr
392 - - for diffusion coefficient of muons in Cu
376 - - for diffusion coefficient of T in Nb 330 - - for diffusion coefficient of T in Pd 1 ~,Cuy,
Pd l_yNiy, Pd~_rVr 145 Prefactor see Pre-exponential factor Preparation methods - - for samples 55~55 - - for superconducting Th and Pd hydrides
187-189, 248-250 Pressure coefficient of superconducting tran-
sition temperature of PdH:, 188,253 Pressure-composition isotherms - - ofLaNisH ~ 222 - - ofMg~Al3H x 219 - - o f N b H x 62 - - of Nio.9Cuo.gHx 174, 175 - - NiHx 173, I74 - - of(Pd alloys) H, 118
- - of PdH~ 78, 80, 81, 85,118, 160, 167, 168, 206
- - of TaHx 63 - - ofTiCr2H ~ 227, 228 - - of TiFeHx 207, 224, 225, 227 - - ofTi 1 yF%H~ 226 - - ofTiFeo.9Ni0.1H ~ 227 - - of VH~ 63, 208 Pressure gauge, manganin resistor as 159 161,
164, 177 PrH~ - - , crystal field splitting in (PrH2) 180 - - , inelastic neutron scattering studies on
(PrH2) 179 - - , magnetic properties of (PrH2) 175, 176,
178 - - , magnetic susceptibility of (PrH2.ol) 179
Prismatic interstitial loops in TaH~ 52 141Pr M6ssbauer line in PrNi5 and PrNisH4.3
161 PrNi2, magnetic properties of 186 PrNis, H solubility in 185 PrNisH4.5, l~lPr M6ssbauer line in 161 PrNisH ~ for H storage 222, 223 Protecting layer, Pd for I50, 151 Proton - - , gyromagnetic ratio of 351 - - , magnetic moment of 351
model see Protonic model - - , rest mass of 351 - - , spin of 351 Proton "fluid" 11 - - diffusion 198, 223, 224 Protonic model 105, 127, 173, 177-179 Pseudo-frequency distribution - - o fa VHo,o4 84 - - offl NbH0.95 80, 82 - - , optical part of, ofThH 2 and ThcH15 89, 90 Pseudo-phonon density 77 Pseudo-random approximation 87 195pt M/3ssbauer line, isomer shifts of, in PdHx
151,152 Pt surfaces, model calculation of chemisorp-
t i o n o f H o n 86, 87
PtH.., formation of 173 Pulse method for diffusion measurements
148 Purification
of H 1 - - of metals from interstitial impurities by
eleetrotransport 300 - - of samples 55-57 Purity of samples 58 PVT data of gaseous hydrogen at high pressures
159, 187
Quadrupolar effects 379 see also Electric quadrupole interaction(s)
- - in Cu for different crystallographic orientations of applied magnetic field 379
- - in Nb 381 in Ta 382
Quadrupole broadening - - , motional narrowing of, in VHx, NbHx,
NbDx, LaHx 242 , powder line shape 235
Quadrupole interaction see Electric quadru- pole interaction(s)
Quadrupole moment of deuteron "351 Quadrupole splitting of 57Fe M6ssbauer reso-
nances in Pdl_yFerH x and Pdl_yF%A1 x 131
378 Subject Index
Quantization axis of nuclear spins 366 Quantum effects in diffusion of H 197, 321 Quasichemical model 99
Quasielastic neutron scattering (QNS) 267- 287, 322, 324, 329, 331, 333 335, 337, 341
- - and NMR 248-250 - - , H-diffusion in presence of impurities studied
by 283- 285 - - , intensity of 273, 274, 281 283 - - - - on NbH x(~ phase) 282 - - - - o n P d D x 283
, on PdH x (,6 phase) 282, 283 , on VH x (e phase) 281
- - on PdH~ (~ phase) 275-277, 150 - - on PdH~ (/~ phase) 277 - - on VHx, TaHx NbHx 277-281 - - , width curves for octahedral-octahedral and
tetrahedral-tetrahedral nearest neighbor jumps in a bcc structure 272, 273
• Quenching experiments 331, 334, 341
Radiochemical technique for diffusion measure- ments 148
Radiographic method for H-diffusion measure- ments 324
Random-walk model 274 Rare earth alloy hydrides for H storage 220,
221 Rare earth hydrides - - , crystalline electric field, ground state of
4f-ions of 136, 137, 159 - - , decomposition of, by mercury 211 - - for H storage 221 - - , magnetic properties of 174-181 - - , M6ssbauer spectroscopy on 136, 159 161 - - , phase diagrams of t 136, 137 Rare earth dihydrides - - , magnetic ordering in 176, 177
, magnetic properties of 176-181 , optical and acoustical phonon dispersion
curves of 89, 90 Rare earth metals, sticking probability of H on
213 Rare earth trihydrides, magnetic properties of
175, 176 Rate equation 301 Rate of diffusion, macroscopic 267 Rate of hydrogenation and dehydrogenation
135 Rate theory for diffusion, classical 217-222,
337 RbH x for H storage 217 Reciprocal lattice - - of hydride structures 14
of~-Ta4D 3 20 of VHx, VD x (fl phases) 24, 25
Reflector, metal hydrides as, in nuclear reac- tors l
Refrigeration by hydride cycles 236, 237
Relaxation amplitude of magnetic aftereffect 290, 291,317
Relaxation curves of magnetic aftereffect , isochronal 290,291
- - , i so thermal 290, 291, 304
Relaxation functions 361, 362 Relaxation maximum of magnetic aftereffect
29t Relaxation method for determination of dif-
fusion coefficient in PdH x 196
Relaxation of muon -- , longi tudinal 358, 359 - - , transverse 358, 360, 371,380
Relaxation rate(s) - - , calculation of 371,372 - - , longitudinal 384 - - , transverse, in e-Fe 389 - - , transverse, in Bi, Nb 384
Relaxation-rate theory, NMR 243-248 Relaxation strength of the Gorsky effect 33,
335 see also Gorsky effect in NbHx (wire and foil samples) 43, 44
Relaxation time(s) 46, 267, 291, 299, 300~302, 305, 310, 317, 318
- - of ~ H , C-D complexes in Ni 309, 310 of elastic modes 35
- - of Me-H, Me-D complexes in fcc alloys 313-315
- - ofmuon spin relaxation 361,362 - - of Ti-H, Ti-D complexes in FeTi alloys
317,318 Relaxed elastic constants 33 Relaxed state 32 Release parameter of trapped H 307 Reluctivity 290, 298, 301 Removal of H atoms from Pd surfaces by chemi-
cal reaction 139 Renormalization of the force constant 8 Reorientation of defects 210, 213~ 214
see also Snoek effect, Magnetic aftereffect • Residence time 271
see also Mean residence time and Mean time-of-stay
Resistivity measurements, low temperature, for investigation of trapping of H in V, Nb, Ta 326 see also Electrical resistivity
Subject Index 379
Resistivity relaxation methods for H-diffusion measurements 324, 329, 341
Rest mass - - of deuteron 351 - - of positive muon 351 - - of positron 351
- - of proton 351 - - of triton 351 Rest system, pion 354 Reversed isotope dependence - - of H diffusion 212, 221, 222, 340, 139, 140 - - of optical modes in PdHx, PdD~ 265
see also Isotope effects RFe2, RFe2H x (R = rare earth), magnetic
properties of 188-190 RFe3, R F % H x (R = rare earth), magnetic
properties of 190, 191 Rh, solubility of H in 306 R h - P d - A g alloys - - , magnetic susceptibility in 254 - - , solubility of H, D in 253 - - , specific heat coefficient in 254 - - , superconducting transition temperature
of H (D) charged, as function of composi- tion of host matrix 253-255
Rigid band model 134, 136, 149, 150, 157, 173, 259, 12~134
Rocking curves 5 8 4 0 Rotating-frame spin-lattice relaxation time
(TI~) 243 RRR (residual resistivity ratio) 58 99Ru M6ssbauer line, isomer shifts of, in PdHx
150, 151 Ruderman-Kit te l -Kasnya-Yosida (RKKY)
interaction 175-177, 180~ 181, i86 Ru, solubility of H in 306
Saddle point(s) 299, 305, 310 Safety of hydrides 218, 226 Scattering functionI~(q,t), intermediate 268 ScH~ - - , electronic density of states of (ScH2) 118 - - for H storage 221 - - , magnetic susceptibility of (ScH2) 170 - - , N M R relaxation times in 245, 247 Screening cloud 295 - - , radius of 295, I3I s-d scattering 180 Second moment of N M R resonance 229 234,
261 - - , accuracy of 232, 233 - - , application of 233 - - , measurements of 232-234 - - , measurements of, on LaHx 231 - - , measurements of, on VH~ 231
- - , structural information from 230 Segregation equilibrium 136 Self-energy term 10 Self-trapping (self-trapped state) 206, 210,
217, 292 Semiconductor(s) (rare earth hydrides) 177 Separation factor - - between H, D in Pd 91-98 - - between H, T in Pd 94, 95, 97, 98 Shape-dependence of H-diffusion coefficient
324 - - i n N b 46, 47, 334, 335 Shear modulus of NbHx 91 Shifting energy 377 Short-range - - interaction 296 - - order 143
see also Hydrogen distribution around M/Sssbauer atoms
Sieverts' law 75, 167, 205 Size factor 54 Small angle neutron scattering experiments,
determination of bulk spinodal in NbD~ by 44, 45
Small polaron 198, 204, 207, 208 - - hopping theory 209-216 SmCos, change of magnetic properties due to
dissolved H in 169, 182, 183 SmC%H:~ for H storage 222,223 SmH x - - , isomer shifts of lS3Eu M6ssbauer line in
160 - - , magnetic properties of 175-177 SmNi 5, H solubility in 185 SmNisH x for H storage 222,223 l l9Sn M6ssbauer line, isomer shifts of, in PdHx
152 Snoek effect 62, 63, 92, 201,209, 289, 306 - - in Fel l x 307, 317 319 - - in NbHx, Ta l l x 289, 331 Solar energy 193
- - harvesting system using VH 2 and TiFeH~.v or LaNisH 6 and MnNisH 6 or VNbH 3 and M n N i s H 6 237
- - , hydride storage of 237 Solid echo (NMR) 23I - - experiment 233 Solidification of H 187 Solubility 306 - - determination of PdH~ - - - - by electrochemical technique 78 - - by UHV technique 79 - - enhancement in Pd alloys 120 - - measurements for determining c(##/#c)
286
380 Subject Index
Solubility (continued) - - o f H i n C o 314,315 - - o f H i n C r 123 - - of H i n F e 306,309,314,315 - - o f H i n L a N i s 182,185 - - of H i n N i 306, 314, 315 - - of H in Pd, effect of lattice defects on 312,
313 - - of H in Pd, effect of stress on 312 - - of H in PdH~ at high H pressures 159 - - of H in PrNi5, SmNi5, NdNis, CeNi s 185 - - of H in Rh, Ru, Ir 306 - - of H in steel 309 Solute-solute interactions in PdH x 98-104 Sound velocity and damping, change of, by
phase transitions 30 Specific heat (electronic) 102, 103, 127 - - anomaly in PdH~ 113-118, 185 - - coefficient - - - - of Ni-Pd-Pt and Rh-Pd-Ag alloys 254
- - of ordered and disordered Pd3Fe 172 , excess, in PdH~ 115
- - of Cr 125 - - of CrH~ 12zV126, 177 - - o fMnH x 125 - - of Pd 111 - - of Pdl-yAgy 129 - - of PdH~ 107, 108,111,259,260,266 - - of Pd-noble metal alloys 266
ofTh4H~s, Th4D15 267 - - of Ti 119 - - of TiH~ 114, 119 - - of V 123 - - ofVl_~,CryH ~ 120
of VH~ 119, 120, 123 - - ofVH 2 119 Spectrometer (for gSR and transverse polari-
zation) 359 Spin 350 - - of deuteron 351 - - of positive muon 351
of positron 351 of proton 351
- - of triton 351 Spin fluctuation(s) in Pd 265 Spin-lattice relaxation see Longitudinal
relaxation Spin-orbit coupling. 296 - - energy 293, 297 Spin precession (of muons) see also Muon spin
rotation (gSR) , frequency of 358-361, 366
- - , sense of 358 360 Spin-spin relaxation see Transverse relaxation Spinodal 13
- - , coherent 41, 44 - - , determination by Gorsky effect 30 - - , incoherent 42 Spinodal decomposition 33, 39 - - , coherent 37 Spinodal temperatures 31, 33, 37, 323
of bulk modes in NbD x 44, 45 SrH2, dissociation temperature of 220 Stacking-fault tetrahedra 308 Stainless steels, isomer shifts of 57Fe M6ssbauer
line due to H loading in 155 Statistical thermodynamics
of PdH x 98-104 of ternary Pd alloys 123-127
Steady state(s) - - measurements 288,289
of electro- and thermotransport 277 Step length for H diffusion determined by
NMR 257, 262 see also Mean jump distance
Step method for diffusion measurements 146 Sticking probability 213 - - o f H o n M g 213 - - of H on rare earth metals 213 Stoichiometry
, deviations from - - - - in NbHx (fl phase) 34 - - , in V2D 13 - - o fNiH x 173, 190 - - of PdH x at high H pressures 167, 170 - - of Pd l_vRh~,Hx 172 Storage - - of heat in metal hydrides 1,237 - - of hydrogen, methods of 202, 203 - - o f hydrogen in metal hydrides 1, 198,
201-242 Strain - - , anelastic 32, 46 -- , ins tantaneous elastic 32 - - , internal 18, 32 - - , total 32 Strain energy - - in Pd alloys 120, 124
model 108 - - of equimolar alkali halide mixtures and a
PdAg a11oy 110 Strain field - - , accumulation of H in high 311-313 - - , externally induced 13 - - , local 283 - - of a point defect 54 Stress(es) - - , external 13 - - , internal 11, 13, 39 Stress field of a point defect 54, 55
Subject Index 381
Stress-free strain 14 Stress gradients, force on dissolved H by 276 Structure change(s), detected by N M R 261 Structure determination, methods of 14, 15 Structure of host metal, influence of, on H
diffusion 342, 343 Sulfur dioxide, inhibition of H-desorption from
LaNisH ~ by 213 Superconducting transition temperature 104,
105 - - , dependence on H, D concentration of, in Pd
251,252 - - , influence of lattice defects on 251 - - , isotope effects in 245 - - of AlH 248 - - of H charged Nb-Pd , Nb Pd-Mo,
Nb Pd-W, N b - R u alloys 247 of H charged PdA1, Pd-Ti alloys 256 of H (D) charged N i - P d - P t and R h - P d - A g alloys 253-255
- - o fH (D) charged Pd-Cu, Pd-Ag and Pd-Au alloys 255-256 of Hfg2, HfV2H 246
- - ofHxTaS 2 247 - - of MoH~ 247 - - of Nbo.78Geo.2> Nbo.TsGeo.22Hx 246
of Nb3Sn, Nb3SnHo. s 246 - - of Pd B, Pd-C, P d - N 257 - - of PdH x, PdD x 89, 108, 188, 247, 251-253 - - - - , pressure coefficient of 188, 252, 253 - - - - , pressure dependence of 187, 188, 252,
253 - - of TaHx 121
ofThC~ _~N x 259 - - - - , pressure dependence of 259 - - o f T h H 2 257 - - of Th4Hls , Th4D15 247, 257, 258
- - , pressure dependence of 258 - - o fT iaAuH x 246
- - of V, Nb, Ta with dissolved gases 246 of VH~ 121
Superconductivity 98, 104, 105, 127 - - , change of, by phase transitions 30 - - in A1H 247, 248
in CrH~ 124 - - in group V-metal hydrides 121 - - in H charged Pd-A1, Pd-Ti alloys 256 - - in H(D) charged N i - P d - P t and R h - P d - A g
alloys 253 255 in H(D) charged Pd-Cu, Pd Ag and Pd-Au alloys 189, 255, 256 in HxTaS 2, ThH3.75, ThD3.75, hydro- genated Nb-Pd , N b - P d - M o , N b - P d W, Nb-Ru, Nb Rh, T h - P d alloys 247
- - in Pd B, Pd C, P d - N 189,257
- - in PdD~ 187, 188,247, 250257 - - in Pd films at high H pressures 189 - - in PdH x 89, 108, 111,90, 167, 185, 187-189,
197, 247, 250~57 - - --., isotope effect in 188, 251-255 - - in Pdl-yMyHx ( M = C u , Ag, B, Ni) 189 - - in TaHx 121 - - in ThC, ThN, ThC l_xNx 258, 259 - - i n T h H x 257, 258 - - in Th4H~5 189 - - in Ti l l 2 116 - - in V2H 121 - - in VHx, NbH~, Tall:,, TiH:~, ZrHx, ThHx,
ThZr2Hx, HfV 2, HfV2H~, HfVzD x, LaHx, UH~, NbaSn, Nb3SnH~, Nb0.TaGe0.22, Nbo.78G%.eeHx, TiBAUH x 246
- - , influence of dissolved gases on 146 - - , - - in V, Nb, Ta, Mo 246 Superlattice reflections 16 Suppression ofmagnet icorder ing 176 Surface behavior of PdH x 84~8 Surface effects (in diffusion) 326 Surface-independent methods (for H-diffusion
measurements) 329, 331,333 Surface kinetics 134-140 Surface migration 134, 135 Surface-sensitive methods (for H-diffusion
measurements) 327, 329 Surface topology 29 Susceptibility see Magnetic susceptibility Symmetry of defects - - , cubic 297, 300
, or thorhombic 297 - - , tetragonal 293, 294, 297, 300 Synthesis, direct, of NiH x 160
Ta - - , binding energies of N-H, O - H and O - D
complexes in 321 , clustering of O in 319, 320
- - , comparison between H and muon diffusion coefficient in 383
, desorption of H from 213 - - , diffusion and location of muons in
379-384, 393, 394 - - , diffusion coefficient of D in 331, 332
, - ,comparison with theory 2t2-214, 217, 222
, , concentration dependence of 335, 336 diffusion coefficient of H in 331, 332
, , activation energy from N M R line narrowing experiments (TaHo.66) 240
- - , - - , comparison with theory 212514, 217, 222
, , concentration dependence of 335-337
382 Subject Index
Ta (continued) , , determined by motional narrowing of
18~Ta M/~ssbaner line 145, 146, 157 159 , -,isotope dependence of 339
effective charge number Z* of H, D in 292 , , concentration dependence of 295, 296
, isotope dependence of 294 , , temperature dependence of 294,295
influence of dissolved gases on super- conductivity in 246
- - , mean time-of-stay of H, D in 332 - - , quadrupole effect in 382
TaD~ - - , acoustical phonon-dispersion curves of
96, 98 - - , change of phonon frequencies in 92 - - , deuteron quadrupole interaction in 236,237 - - , lattice expansion of 66, 67
, lattice structure of 18-21
- - , line narrowing, quadrupole interactions in 241
- - , low-temperature phases of 20 , optical modes in 81, 83
TaH x - - , acoustical phonon-dispersion curves of
96, 98 - - , axial asymmetry parameter of 237 - - , axial ratios of or thorhombic (Tall, fi phase)
19 - - , calorimetric results on 38 - - , domain pattern in 51, 52 - - , DTA studies on 20, 28, 35, 37 - - , eutectoid decomposition in 37, 51
for H storage 228 - - , formation of, using catalysts 215 - - , hydride morphologies in 5 0 5 2
, , electron microscope results 52 - - , - - , metallographic results 50-52 - - , incoherent precipitates in 52 - - , i s o m e r shifts of ~81Ta M/Yssbauer line in
155-157 - - , Knight shift in 260 - - , lattice expansion of 66, 67
, lattice structure of 18-2I , magnetic susceptibility of 121, 170, 171,
1 7 4 , 35 - - , metallography on 35 - - , monotectoid point in 37 - - , optical (localized) modes in 8t, 83, 331 - - , peritectoid transition in 51 - - , phase diagram of 135, 35
, schematic 12 - - , pressure-composition isotherms of 63 - - , prismatic interstitial loops in 52
- - , quasielastic neutron scattering (quasielastic width) on 277-279
- - , relative lattice parameter change of 57, 66 - - , relative volume of 67 - - , superconductivity in 121,246
, transmission electron microscopy on I9, 20, 52
18~Ta M/Yssbauer line , isomer shifts of, in TaH~ (c~ phase) 155 157
- - , motional narrowing, broadening by H diffusion of 145, 146, 157-159, 324
Target specimen for muons 359 - - , size of 355, 358 TbCo3H x for H storage 223 T bC osH x for H storage 222, 223 TbHx, magnetic properties of 175-177 Telescope, positron 358-360 Temperature - - of spinodal see Spinodal temperatures - - w i d t h of a phase transition see Phase
transition(s) Temperature-entropy diagram 4, 5
Ternary hydrides for H storage 21l, 224, 229 Ternary systems based on Pd 118-123
Tetrahedral (interstitial) sites 10, 79, 326, 366, 370, 380, 381, 386, 387, 390, 392, 393, i5, 20-25, 34, 65, 66, 184, 185, 314
Tetrahedral-tetrahedral jumps 215, 270 273, 276, 279, 337
Th - - , activation energy for H diffusion in, from
N M R line narrowing experiments (ThH3.5) 240
, hydrJding kinetics of 214 Th2A1, hydriding kinetics of 213 Th-alloy hydrides (AI, Ag, Co, Fe, Mn, Ni, Ti,
Zr) for H storage 229 ThC, superconducting transition temperature
in 259
ThC i _ ~N X - - , superconducting transition temperature in
259
~ , - - , pressure dependence of 259
T h C o s H x for H storage 229
Thermal conductivity of hydrides at high H pressures 195, 196
- - of Pd 196
- - , pressure coefficient of, for Pd, Mn 196
Thermal compressor, hydrides used for i Thermal defects 29 Thermalization o f m u o n s 355, 373 - - , time of 373 Thermally activated jumps 197, 198
Subject Index 383
Thermally activated tunneling 198, 210, 214, 216, 222 see also Tunneling, phonon assisted
Thermodynamic data of H - - in Pd 125 - - in Pdl_yAgy and Pdl .vSny I25 Thermodynamic factor 146 - - , concentration dependence of,
in Pdo.6Ag0.~H x 147 Thermodynamics - - of hydrides 209-210 - - of PdH~ 168
see also Statistical thermodynamics Thermodynamic properties at high H pressures
165-180 Thermometer , hydrides as 237, 238 Thermomigrat ion see Thermotranspor t Thermo-osmosis 289 Thermopower
- - of hydrides at high H pressures 189-192 - - o fNi 1 yCurH , 191
, hysteresis in 191 - - o fNi 1 yFeyH x 191, 192
, hydrostatic change of 192 - - o f N i H x 177, 189, 190
of N i -Pd alloys 177 - - of PdH x 189, 190 Thermotranspor t of H - - , causing H-embrit t lement 301 - - in electron microscopy investigations 301 - - in metals 273-304 - - in Ti 273 - - in Zr-alloy fuel cladding 301 ThTF%
, Curie point of 193 - - , hydrogen induced magnetic ordering in
193 ThHx - - for H storage 229
optical phonon density of states of (ThH2) 267, 268
, superconducting transition temperature in (ThH2) 257
- - , superconductivity in (ThH2) 246 - - , vibrational spectra (optical and acoustical)
of 89, 90 Th4Hls , Th4D15
- - electronic specific heat of 267 - - optical phonon densities of states of
(Th4Hls) 267, 268 , preparation methods for 248,249
- - superconducting transition temperature in 257, 258
- - , superconductivity in i89,247 Th6Mn23, magnetic properties of 191, 192
Th6Mn23H30 - - , Curie point of 191 - - , magnetic properties of 191, 192 ThN, superconducting transition temperature
in 259 ThNisH ~ for H storage 229 T h - P d alloys, effect of H on superconductivity
of 247 ThZrzHx, superconductivity in (ThZrzH7)
246 Ti
, activation energy for H diffusion in, from N M R line narrowing experiments 240
- - , desorption of H from 213 - - , diffusion of H, T in, studied by N M R 262
, effective charge number Z* of H. D, T in 291
- - , Hall field electrotransport o fT in 296 - - , heat of transport Q* of H in 297
, - - , dependence on concentration and lattice structure of 300
- - , hydriding kinetics of 214 - - , removal of oxide film on 212 - - , step length of H diffusion in, identification
by N M R (7-Till:,) 257 - - , structure dependence of H-diffusion
coefficient in 342
Ti3AuHx, superconductivity in 246 TiCoH~ for H storage 226
TiCr2Hx, pressure-composition isotherms of 227, 228
TiCu, Ti2Cu, TiCu 2, decomposition of, due to hydriding 227
TiFe, fast H-uptake in 214
TiFeHx as hydrogen reservoir 230-233
- - , desorption of H from (TiFeH 1.9) 213 - - , dissociation pressure of 205, 224
, effect of Ni substitution on 226, 227 , enthalpy and entropy of formation of
(TiFeH1.0) 209 - - for automotive propulsion 233-235
for hydride engine s 236 , H density in (TiFeH1.93) 216 , hysteresis effects in 225
- - , isomer shifts of STFe M6ssbauer line in 155
- - , phase diagram of 224, 225 - - , pressure-composition isotherms of 207,
224, 225, 227 - - , - - , effect of composition on 226 - - , safety of 226
Ti 1 _yFGH x, pressure-composition isotherms of 226
384 Subject Index
TiFeo.9Ni0.zH ~, pressure-composition iso- therms of 227
TiH~ - - , antibonding states in (Till2) 117, 118 - - , b o n d i n g states in (TiH2) 117, 118 - - , electronic density of states of 114,
(Till2) 117-119 - - , electronic specific heat of 114, 119 - - , enthalpy and entropy of formation of
(TiHt.97) 209 - - for H storage 224 - - , H density in (Till2) 216 - - , lattice structure of (Till2) 112, 113 - - , m a g n e t i c susceptibility of 114, 119, 170,
171 - - , N M R relaxation times in 245, 247 - - , N M R second moment measurements on
(7-TiHx) 230 - - , occupancy of tetrahedral sites in (y-TiHx)
230 - - , photoemission of 116 - - , superconductivity in (Till2) 116, 246 - - , T l e T i n 259 - - , x-ray spectroscopy on (Till2) 115 Ti -H complexes in Fe 295, 296 - - , activation energy and preexponential
factor for 317, 318 - - , magnetic aftereffect relaxation spectrum of
314 318 - - , orientation aftereffect of 316
Time-differential technique 359
Time-lag methods for diffusion measurements 140 151
Ti2Ni-TiNi mixtures as electrodes in batteries 236
TiNiHx. 4 for H storage 226,227 TiT x, N M R relaxation times in 245, 247
Til yVrHx - - , electronic density of states of 114 - - , lattice structure of 112, 113
, magnetic susceptibility of 114, 115, 174 - - , phase diagram of 113 TiVI.~,H4. 6 for H storage 229 TiV,H 8 for H storage 229 T-matrix approximation 274 TmF% - - , Curie point of 188 - - , magnetic properties of 188-190
TmFezH x - - , Curie point of 188 - - , magnetic properties of 188, 189 TmH~ - - , lattice expansion of 70 - - , magnetic properties of 175-177
Topping cycle(s) 1, 2-9 - - using LaNisH~, MgzNiH ~ 4-7 - - , work producing, using Mg2NiH x 7-9 Tracer diffusion coefficient 46, 323, 324,
334-337 see also Diffusion coefficient
Transfer catalysis, hydrogen 134 Transference catalyst 78,214 /~ ~ c~ transition enthalpies of PdHx 82~4 Transmission electron microscopy (TEM)
14-18, 19, 20, 24, 25, 49-52, 54 - - on NbH x, NbD~ 15 18, 32, 49-51 - - on TaHx, TaD~ 19, 20, 52 - - o n V H ~ , V D x 24, 25, 54 Transverse relaxation time (T2) 243-250 Transverse spin polarization 356, 364, 378 Trap density 307 Trapped H, transport of, by moving disloca-
tions 316, 317 Trapping - - of H 274, 326, 328
of H by carbides in Fe 315 - - of H by dislocations 316-319 - - of H by dislocations in iron 313 - - of H by impurities 319-326
- - of H by substitutional alloying elements 325, 326
- - of H b y V i n N b 325, 326 - - of H in Nb by O or N impurities 320, 321
of H in single vacancies 310 - - of H in V, Nb, Ta, investigated by low
temperature resistivity measurements 326
- - of muons 365, 372, 380, 382, 384, 389, 393 - - parameters 307 Tricritical point 29 Tricritical temperature(s) 28 Trihydride phases 18 Triple point temperature 31 Trit ium diffusion 212, 221,262, 329, 331,338-
340, 148 see also Diffusion coefficient
Trit ium-metal systems 31 Triton 352
, gyromagnetic ratio of 351 - - , l i f e time of 351 - - , magnetic moment of 351 - - , r e s t mass of 351
, spin of 351 Tunneling - - , coherent 197, 204, 208, 384, 394
experiments on AIH 248 - - experiments on PdHx, PdDx 189, 261-264 - - m a t r i x element 202-204, 206, 207, 209,
210, 21~216
Subject Index 385
- - matrix element, effective 207 - - probability 292, 312
- - process, phonon assisted (incoherent) 198, 210, 214, 216, 222, 290, 291, 376, 394 states 201,204-209, 224, 312
Two-phase region of PdHx 82 , plateau pressure of 81
U
, activation energy for H diffusion in, from NMR line narrowing experiments (UH3) 240
, hydriding kinetics for 214 UH~ -- , Curie point of 182 - - , dissociation pressure of 205 - - , enthalpy and entropy of formation of
(UH3) 209 for H storage (UH3) 229
- - , magnetic properties of 181, 182 - - , superconductivity in (UH3) 246 Ul_~NbyHx, hysteresis in H absorption in
2O8 Unit cell of VxD 23
V
-- , binding energy of O D complexes in 321 , comparison between H- und muon-
diffusion coefficient in 383 - - , diffusion and location of muons in
379-384, 393, 394 - - , diffusion coefficient of D in 333 - - , diffusion coefficient of H in 333
- - - - , comparison with theory 212-214, 217 , , concentration dependence of 335 , , direct measurement by NMR pulsed gradient method 252
- - , effective charge number Z* of H, D in 291
, , concentration dependence of 295,296 , , isotope dependence of 294 , -, temperature dependence of 294,295 , heat of transport Q* of H in 298 , identification of H-diffusion mechanism in
250 - - , influence of dissolved gases on supercon-
ductivity in 246 - - , mean time-of-stay of H, D in 333 - - , motional narrowing of muon resonance in
38O Vacancies
, electron, in the d-band 173 in D sublattice of VD~ 25
Valence electron concentration 121, 127
Van Hove selfcorrelation function '268, 269, 272
Van Vleck paramagnetism 178 V0.TCr0.3, magnetic susceptibility of 171 V1 _yCryHx - - , electronic specific heat of 120, 259
, Knight shift in 259 - - , T l e i n 259 V0.9Cr0.1H x, dissociation pressure of 205 VDx -- , deviations from stoichiometry (VzD) 23
, dideuteride phase of 22, 26 - - , D T A o n 41,42 - - , hypostoichiometry in 23 - - , lattice expansion of 67-69 --, latt ice structure of 23-26 - - , line narrowing, quadrupole interactions in
241 , nuclear quadrupole splitting (host metal) in
237 - - , occupancy of octahedral sites in 237 - - , optical modes in 81, 83, 84
, phase diagram of 40-42 , ,schematic 43
- - , quadrupole interaction in 236, 237 - - , reciprocal lattice of (/? phase) 24, 25
, temperature dependence of lattice parameter of(/? phase) 24
- - , unit cell of (V2D) 23 Vector coupling constants 352 VH x
, calorimetric study on 22 , dihydride phase of 21, 23
- - , dissociation pressure of 205 - - , D T A o n 22, 39, 40
, electron diffraction on 22 - - , electronic density of states of 118, 119, 122,
123 - - , electronic specific heat of 119, 123
, enthalpy and entropy of formation of (VH02, VH2.0) 209
- - for H storage 228 - - , H density of(VHz) 216 - - , hydride morphologies in 53, 54
, , electron microscope results 54 , , metallographic results 53, 54
hysteresis in H absorption 207, 208 - - in hydride refrigerators (VH2) 237 - - , Knight shift in 260 - - , lattice expansion of 67-69 --, latt ice structure of 2 1 ~ 3
, line narrowing, quadrupole interaction in 242
- - , magnetic susceptibility of 119, 121, 123, 170, 171,174
386 Subject Index
VHx (continued) , N M R second moment measurements on
231 - - , nuclear quadrupole splitting (host metal) in
237 - - , occupancy of octahedrai sites in 237 - - , optical (localized) modes in 81, 83, 84, 334 - - , phase diagram of 38~40
, , schematic 12 , pressure-composition isotherms of 63, 208
, pseudo-frequency distribution of 84 - - , quasielastic intensity of 281 - - , quasielastic neutron scattering (quasi-
elastic width) on 277 - - , reciprocal lattice of (j8 phase) 24, 25 - - , relative length change of 68 - - , relative volume change of 68 - - , solvus of 38,39 - - , structure of 120 - - , superconductivity in 121,246
- - , temperature dependence of lattice parame- ter of(/? phase) 24
- - , transmission electron microscopy on 24, 25, 54
- - , x-ray spectroscopy on 121 Virtually bound states 130 Voids 308,309 Volume change 7, 55, 56
see also Lattice expansion Volume of solution, partial molar 311
in Ni and Fe 315
Waste heat, use of 216 Water, H density in 216 Wave function of muon 366 - - , finite extension of 379 Wave packets 216, 217 WH2, absence of formation of 118 Width curve(s) (quasielastic neutron scattering)
for octahedral-octahedral and tetrahedral- tetrahedral nearest neighbor jumps in a bcc structure 272, 273
Width function (quasielastic neutron scattering) 271
Width of quasielastic peak, concentration dependence of 278
Wiedemann-Franz law, devi~ttions from, in PdHx 196
Wires, elastic relaxation (Gorsky effect) on 21, 29, 36, 41,335
Work-producing topping cycle 8
X-ray diffraction 14 - - on NbH0.a3 28
X-ray investigations 194, 195 - - on CrH x 178 - - on hydrides at high H pressures 194, 195 X-ray method (for H-diffusion measurement)
324, 335 X-ray spectroscopy - - on CrHx 124 - - on NbH:, 121 - - on Ti l l 2 115 - - on VH x 121 X-ray topography 58 - - , Berg-Barrett 58, 59
Y, effective charge number Z* of H in 291 Y alloys with Mn, Fe, Co, Ni, hydrides of, for
H storage 223 YbHx, magnetic properties of (YbH2) 180 YCo2, magnetic properties of 186 YCos, effect of degassing on lattice parameter
of 183 YFe 2 - - , Curie point of 188 - - , magnetic properties of 188, 189 - - , M6ssbauer measurements on 190 YF%H4 - - , Curie point of 188 - - , magnetic properties of 188 190 - - , M/Sssbauer measurements on 190 YFe3, YFe3H3 - - , Curie point of 191 - - , magnetic properties of 190, 19l YH~ 221 - - , ~6°Dy M6ssbauer line in (YH2) 159 - - , electric quadrupole interactions in (YH2)
160 - - , electronic density of states of (YH2) 118 - - , 166Er M/Sssbauer line in (YH2) 159 - - for H storage 221 - - , ground state of 4f-ions in (YH2) 159, 160 ~ , lattice expansion of 70 - - , magnetic susceptibility of (YH2.8) 170 Y6Mn23 - - , Curie point of 191 - - , magnetic properties of 191,192 Y6M23H25, magnetic properties of 191, 192 YNisH x for H storage 222, 223 (Y, Th) NisH x for H storage 222,223
Zeemann level(s) of muon in magnetic field 361
- - quadrupolar shift of 235 Zero-point energies 318 - - of PdH x, PdD~ 89 Zero-point motion of H, D in Pd 265
Subject Index 387
Zirkaloy 2 - - , heat of transport Q* of H, D in 298
, , isotope dependence of 299
Zn, muon ium precession frequency in 374
Zr - - , activation energy for H diffusion in, from
N M R line narrowing experiments (ZrH1.4) 240
- - , effective charge number Z* of H, D, T in 2.Ol
- - , Hall field electrotransport o f t in 296
- - , heat of transport Q* of H in 297
-, dependence on concentration and lattice structure of 300
, -, temperature dependence of 299 hydriding kinetics of 214
, removal of oxide film on 212
Zr-alloy hydrides (ZrVzHx, ZrCrzHx, ZrFe2H~, ZrCo2H x, Zr2CuH x, Zr2NiH ~, ZrMo2Hx) for H storage 227
ZrHx - - , decomposition in molten AI 211 - - , dissociation pressure of 211 - - , enthalpy and entropy of formation of
(ZrHz) 209 , 166Er M/Sssbauer line in (ZrHI.5) 160
- - for H storage 224 - - , ground state of 4f- ions in 160
, magnetic susceptibility of (ZrH2) 170 , N M R relaxation times in 247 , superconductivity in (ZrH2) 246
Z r - H complexes in Fe 295 ZrNiH2, dissociation pressure of 211 ZrNiH x for H storage 227 Zwischenreflexstreuung 58