Brewer D.F. — Progress in Low Temperature Physics. Volume X :: Электронная библиотека попечительского совета мехмата МГУ

Главная Ex Libris Книги Журналы Статьи Серии Каталог Wanted Загрузка ХудЛит Справка Поиск по индексам Поиск Форум

Авторизация

Поиск по указателям

Brewer D.F. — Progress in Low Temperature Physics. Volume X

Обсудите книгу на научном форуме

Нашли опечатку?
Выделите ее мышкой и нажмите Ctrl+Enter

Название: Progress in Low Temperature Physics. Volume X

Автор: Brewer D.F.

Аннотация:

The present volume is largely concerned with helium, as the variety of physics encompassed in the thermal, magnetic and hydrodynamic properties of liquid and solid helium is considerable - it is in many ways a model condensed system.

Язык:

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Год издания: 1986

Количество страниц: 465

Добавлена в каталог: 13.01.2014

Операции: Положить на полку | Скопировать ссылку для форума | Скопировать ID

Предметный указатель

Rietschel, H.      400 406 419 425 406 424 425; G. Winter H.
Rieubland, J.M.      151 368; T.O.
Rigid muffin tin      404
Rigid-ion approximation      403 404 406
Rijllart, A.      151 368; T.O.
Ripplons      179 352
Ristig, M.L.      175 567; K.E.
Roach, P.D.      68 72 124 136; P.R.
Roach, P.R.      124 136 68 72; P.D.
Robert, J.B.      177 368; M.
Roberts, R.E.      239 369
Robinson, A.L.      239 364; I.
Rodrique, V.      88 134; R.
Rosenbaum, R.L.      359 369
Rotating cylinder      39
Rotating frame      8 9
Rotating neutron stars      23
Rotating superfluid      4
Ruckenstein, A.E.      311 340 369 227 344 345 346 367; L.P. Siggia E.D.
Rudnick, I.      352 353 364; K.R.
Ruvalds, J.      375 423
Saam, W.F.      352 369 175 365; D.O.
Sai — Halasz, G.A.      92 93 94 104 122 125 136 137
Salomaa, M.M.      16 19 20 21 22 23 24 27 28 29 51 59 69 70 72 23 30 31 32 38 71 42 51 61 62 63 65 66 72; P.J. Mineev V.P. Seppala H.K.
Salonen, K.      178 180 361 369 196 223 229 232 359 370; T.
Salonen, K.T.      178 179 184 369
Sample, H.H.      95 13 7
Sanders Jr, T.M.      83 136; J.
Sandhas, W.      253 364; E.O.
Santini, M.      117 118 134; L. Careri G.
Saslow, W.      354 355 366; R.A.
Sauls, J, A.      21 23 72
Sauls, J.A.      6 45 49 51 55 57 58 67 68 70; A.L
Savignac, D.      123 137 133 134; J.
Scalapino, D.J.      373 423 400 422; J.E.
Scaramuzzi, F.      80 91 134; G.
Schaffrath      302 370; B.J.
Schell, G.      406 423
Schiff, D.      333 369
Schmid, E.W.      253 369
Schmidt, K.E.      149 321 323 328 333 334 368; R.M.
Schober, H.R.      406 408 420 422; D
Schopohl, N.      51 67 72 13 19 55 71; T.
Schr $\ddot{o}$ dinger equation      35 36 37 50 64 65 67
Schrieffer, J.R.      412 421 375 376 400 421 373 423; J. Berk N.F. Scalapino D.J.
Schwarz, K.M.      76 81 137
SCL current      86 90 100 114
SCL current mobility      89
SCL technique      127
Scoles, G.      170 364; R.
screening      403 404
Second-order recombination      238 241
Second-sound surface mode      354
Seidel, G.      204 227 368; R.
Seitz, F.      128 757
Selection rule      237
Self-energies      382
Seppala, H.K.      51 59 60 61 62 63 65 66 72
Serene, J.W.      67 383 72 423 21 23 70 72; W.F. Sauls J.A.
Shal’nikov, A.I.      91 92 137 91 94 95 135 84 89 92 93 96 108 135 136; E.L. Keshishev K.O.
Sham, L.J.      399 423 400 422 423; M. Kohn W. Rietschel H.
Shen, S.Y.      352 365; J.R.
Shevchenko, S.I.      352 369
Shewmon, P.G.      122 137
Shih, S.      170 365; D.M.
Shikin, V.B.      76 81 83 91 101 102 103 104 107 123 124 129 137 108 135; V.B.
Shinkoda, I.      206 207 220 221 229 369; M.W.
Shirokovskii, V.P.      406 408 424; A.G.
Shizgal, B.      303 306 310 365; A.J.
Shlyapnikov, G.V.      181 183 184 185 220 223 231 232 233 234 240 241 259 280 290 292 301 303 311 319 320 340 351 359 362 367; Yu
Siggia, E D.      311 340 369 337 367 369; D.A. Ruckenstein A.E.
Silvera, I.F.      148 150 153 155 161 169 174 175 188 189 192 194 196 197 198 204 205 207 209 253 254 256 336 340 347 358 360 369 291 311 318 364 365 206 207 222 363 366 337 339 349 366 178 179 184 369 153 189 196 203 206 207 216 217 218 219 220 221 223 224 229 230 231 232 235 258 358 359 369 163 207 208 214 216 220 227 228 345 370 337 335; R.M.C. Berlinsky A.J. Godfried H.P. Goldman V.V. Matthey A.P.M. Salonen K.T. Sprik R. van G.H. Walraven J.T.M.
Simhony, M.      88 146; A.
Simmons, R.O.      95 127 131 135; S.M.
Simola, J.T.      23 30 31 32 38 40 71 51 61 62 63 65 66 72;; P.J. Pekola J.P. Sepp H K.
Simons, A.L.      406 420 423
Simpson, R.W.      406 422; D.
Single-atom properties      156
Single-valuedness      51
Singlet state      10 164
Singly quantized singular MH texture      59
Singly quantized vortices      8 20 54 56
Singular $\hat{l}$ texture      53
Singular cores      51
Singular singly quantized vortices      51 58 62 66
Singular superflow      53
Singular textures      51 53
Sinha, S.K.      401 406 408 420 422; B.N.
Slater, J.C.      401 424
Smith Jr,J.B.      83 84 129 137
Smith, D.A.      189 197 198 365 163 174 188 365; R.W. Crampton S.B.
Smith, E.N.      356 365; B.C.
Smith, H.      24 25 36 72 26 27 38 39 40 71; K.W.
Smith, H.G.      406 408 421; W.H.
Smith, R.A.      327 333 334 367; E.
Soft core      59
Solid-body rotation      7 8 50
Souza, S.P.      195 365; S.B.
Space-charge limited current transients      88
Spear, W.E.      76 137
Specific-heat anomaly      11
Spectator atom      232
Spectator index      261
Spectrum in bounded container      37
Spin current      342
Spin degeneracy      326
Spin density      32 33 63
Spin diffusion coefficient      342
Spin exchange      303 361
Spin part of the order parameter      63
Spin polarization      160 173 343
Spin waves      39 151 226 340
Spin waves in a ferromagnet      5
Spin-fluctation model      21
Spin-fluctuation effects      411
Spin-polarized deuterium ( $D\downarrow$ )      148
Spin-polarized hydrogen ( $H\downarrow$ )      148 151 355
Spin-polarized tritium ( $T\downarrow$ )      148
Sprik, R.      153 189 196 203 206 207 216 217 218 219 220 221 223 224 229 230 231 232 235 258 358 359 369
Springett, B.E.      83 121 137
Square lattice      56 62
Stabilization      153 173 188
Stabilization of $D\downarrow$       204
Stabilization of $H\downarrow$       189
State polarization      160
Statt, B.W.      163 203 206 207 214 218 221 227 229 253 258 303 311 345 369 163 189 211 212 241 259 366 206 207 220 221 229 369; W.N. Reynolds M.W.
Stein, D.L.      6 23 72 45 49 51 55 57 58 67 68 70 61 63 65 66 67 72; A.L. Sauls J.A. Vulovic V.Z.
Stewart, A.T.      84 137; W.
Stewart, G.R.      10 374 72 424
Sticking probability      178 181
Strain field      132 133
Strained crystals      91
Strong-coupling theory      12 21 411
Structure of cavity      129
Structure of ions      76 109
Stutzki, J.      184 365; J.
Stwallcy, W.C.      176 177 188 207 239 240 329 369 171 300 370; Y.H.
Sullivan, N.      95 126 137
Super-current      44
Superconductors      10
Superconductors, type — II      10
Superfluid density tensor      44
Superfluid turbulence      69
Superfluid velocity      5 43 47 48 52 55
Superfluid velocity for nonuniform flow      44
Superfluid velocity in the B phase      15
Superfluid vorticity      48
Surface chemical potential      347
Surface collisions      179
Surface coverage      154 178

Surface energy      25
Surface layer      26 38
Surface recombination      188
Surface recombination rate constant      208 213
Surface region      30
Surface tension      231 358
Surfaces      346
Swenson, C.A.      95 137; H.H.
Swihart, J.C.      406 421 424; M. Tomlinson P.G.
Symmetrized states      241
Tabakar, V.P.      400 422; V.P.
Takano, Y.      356 365; B.C.
Tastevin, G.      345 370
Tedrow, P.M.      413 415 421; J.A.X.
Tewordt, L.      13 19 55 71; T.
Texture of the B phase      13
Textures in rotating container      24 68
Textures, topologically equivalent      52
Theodorakis, S.      36 38 41 72 21 70; A.L.
Theory of positive-ion mobility      123
Thermal escape      203
Thermodynamic conjugate      322
Third-order decay constant      231
Third-order recombination      238 259
Third-sound waves      353
Thomas, A, W.      253 370 239 241 258 366; J.M.
Thomson, G.P.      85 137; J.J.
Thomson, J.J.      85 137
Thomson, J.O.      80 91 734; G.
Thouless, D.J.      352 367; J.M.
Three-body center of mass      241
Three-body recombination      361
Thuneberg, E.V.      69 70
Tight-binding approximation      65 406
Time of flight      86 89 90 94
Tipped magnetic field      62 66
Titus, W.J.      116 136; L.H.
Tjukanov, E.      178 180 361 369 196 223 229 232 359 370; K. Tommila T.
Tkachenko, V.K.      9 72
Tomizuka, C.T.      84 121 134; V.E.
Tomlinson, P.G.      406 408 424
Tommila, T.      196 223 229 232 359 370 178 180 361 369 362 363 368; K. Lovelace R.V.E.
Topological constraints      62
Topologically distinct rotations      22
Torsional oscillations      41
Tosi, M.P.      402 421; F.
Tough, J.T.      3 72
Toulouse, G.      55 70; P.W.
Transient response      87 89 90 97 115
Transient space-charge limited (SCL) currents      85 86
Transit time      88 91
Transition in vortex cores      69
Transverse excitation      64
Transverse modes      38
Transverse NMR      39 65 66
Transverse NMR satellites      40
Transverse response      34 35
Trapped charge      86 89 91 94 99 127
Triangular lattice      51 58
Triftshauser, W.      84 137
Triplet      164
Triplet p-wave order parameter      42
Triplet pairing      11 413 414
Triplet potential      173
Tsuneto, T.      16 23 27 71 50 56 57 58 70 68 71; T. Nakahara M. Ohmi T
Tsymbalenko, V.L.      86 89 90 94 135; A.V
Tung — Li, H.      102 135; E.P.
tunnelling      77 78 79 105 112 113 127 132 133
Twerdochlib, M.      171 172 366 368; J.E. Milleur M.B.
Two quanta of circulation      61
Two-dimensional harmonic oscillator      39
Two-dimensional superfluidity      150 351 363
Two-dimensional surface      154
Two-particle Green’s function      413
Type — I lattice      58 62 67 68
Type — I texture      57
Type — II superconductors      67
Uang, Y.H      171 300 370
Ultrasonic attenuation      62 67
Uniform field      63
Uniform translation      43
Unitarity      23
Unsymmetrized states      242
Upper critical field      51
Vacancies      76 77 101 103 104 105 106 107 108 109 110 114 120 125 127 128 130 131 132 133
Vacancion      78 109 110 111 112 113 122 128 131 132
Vacancy mechanism      133
Vacancy waves      122
Vacancy-assisted mechanism      105 122 123 129 130
Vacancy-assisted mobility      103 106
Vacancy-assisted motion      128 132 133
Vails, O.T.      21 71 400 423; K. Levine K.
Valeo, E.J.      151 356 367; R.M.
van den Eijnde, J.P.H.W.      220 301 311 316 317 370 302 370 291 311 312 313 318 3 54; R.M.C. Verhaar B.J.
Van der Waals interaction      166
van der Waals recombination      241 246 255
van Yperen, G.H.      163 207 208 214 216 220 227 228 345 370 222 223 311 313 317 319 367 178 179 184 359 203 206 207 216 217 218 219 220 221 235 258 369; A. Salonen K.T. Sprik R.
Vapor compression      194
Varma, C.M.      406 420 423; A.L.
Vartanyantz, I.A.      220 223 231 232 233 234 240 241 259 280 290 292 301 303 311 319 320 351 359 362 3 57; Yu
Vauge, C.      80 737
Veprev, A.G.      406 408 424
Verhaar, B.J.      203 232 282 293 302 370 291 311 312 313 318 354 220 234 288 291 365 220 301 311 317 370; R.M.C. de L.P.H van J.P.H.W.
Verlet, L.      333 369; D.
Vessot, R.F.C.      157 366; H.
Vibration-rotation levels      240
Vilches, O.E.      351 368; E.V.L.
Vinen, W.F.      3 72
Virial expansion      351
Vlasov, S.V.      410 424
Voermans, M.A.J.      302 370; B.J.
Void radius      129
Volovik, G.E.      23 27 51 52 58 59 62 63 72 21 23 26 30 31 32 38 39 40 41 71 16 19 20 21 22 23 24 27 28 29 51 59 69 70 72 51 59 60 61 62 63 65 66 72; P.J. Pekola J.P. Salomaa M.M. Sepp H.K.
von Barth, U.      400 402 424; A.R.
Vonsovsky, S.V.      373 424
Vortex core      3 7 16 23 27 42 49 53
Vortex core structure      18
Vortex density      8
Vortex dynamics      69
Vortex in the A phase      43
Vortex lattice      9
Vortex lines      30
Vortex nucleation      4
Vortex orientation energy      29
Vortex ring      116 117 118
Vortex waves      69
Vortex-core radius      15
Vortex-orientation contribution      28
Vortices in superconductors      10
Vredenbregt, E.J.D.      302 370; B.J.
Vulovic, V.Z.      61 63 65 66 67 72
Wakabayashi, N.      406 408 421; W.H.
Walecka, J.D.      36 46 47 383 70 422; A.L.
Wall coverage      194
Wall recombination      194
Walraven, J.T.M.      155 166 167 188 189 192 197 198 254 335 337 370 223 311 313 317 319 367 220 234 291 365 188 199 205 206 207 209 211 212 213 214 255 368 178 179 184 369 153 189 196 203 206 207 216 217 218 219 220 221 223 224 229 230 231 232 235 258 358 359 369 148 150 153 161 174 188 189 194 196 197 204 205 207 209 253 254 256 336 340 369 163 207 208 214 216 220 227 228 345 370; L.P.H. Lagendijk A. Matthey A.P.M J.T.M. Salonen K.T. Silvera I.F. Sprik R. van G.H.
Warnke, M.      13 19 71; T.
Washburn, J.      119 137
Wcak-coupling limit      12
Wcisz, S.Z.      88 146; A
Weak-coupling GL regime      35
Weak-coupling parameters      19
Weakly interacting Bose gas      337
Weber, W.      402 424 406 420 423; A.L.
Weinrib, A.      163 174 188 365; S.B.
Werthamer, N.R.      15 70; R
Wheatley, J.C.      11 34 72 68 71; D.N.
Whitehead, L.A.      174 187 188 209 224 366; W.N.
Whitmore, M.D.      401 406 424
Whitten, J.L.      80 137; C.

1 2 3 4 5

О проекте