Prigogine I., Rice S.A. — Advances in CHEMICAL PHYSICS. Volume XC :: Электронная библиотека попечительского совета мехмата МГУ

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Prigogine I., Rice S.A. — Advances in CHEMICAL PHYSICS. Volume XC

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Название: Advances in CHEMICAL PHYSICS. Volume XC

Авторы: Prigogine I., Rice S.A.

Аннотация:

This series is devoted to a wide variety of developments in the field of chemical physics. It features comprehensive analyses of subjects of interest, in the hopes of both educating the novice and stimulating further research.

Язык:

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Год издания: 1995

Количество страниц: 404

Добавлена в каталог: 05.12.2013

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Предметный указатель

Semiclassical quantization, classical dynamics, Smale horseshoe and symbolic dynamics      164—170
Semiclassical quantization, classical dynamics, thermodynamic formalism      170—175
Semiclassical quantization, Coulomb Hamiltonian      267—268
Semiclassical quantization, Coulomb Hamiltonian, B-O Hamiltonian compared with      272—273
Semiclassical quantization, energy domain, equilibrium-point quantization      190—193
Semiclassical quantization, energy domain, periodic-orbit quantization      194—223
Semiclassical quantization, Feynman path integrals      132—145
Semiclassical quantization, Feynman path integrals, Green function as resolvent of Jacobi — Hill operator      139—140
Semiclassical quantization, Feynman path integrals, h-expansion of propagator      141—145
Semiclassical quantization, Feynman path integrals, propagators as      132—134
Semiclassical quantization, Feynman path integrals, stationary-phase integration      134—136
Semiclassical quantization, Feynman path integrals, variation and Jacobi — Hill equation      136—139
Semiclassical quantization, flowchart of Hamiltonian and classical orbits and      341—342
Semiclassical quantization, h-expansion and anharmonicities      347—349
Semiclassical quantization, historical background      111—114
Semiclassical quantization, hydrogen negative ion ( $H^{-}$ )      333—337
Semiclassical quantization, limits of      349—351
Semiclassical quantization, matrix Hamiltonians      246—267
Semiclassical quantization, matrix Hamiltonians, conical intersection and geometric phase      259—267
Semiclassical quantization, matrix Hamiltonians, diagonalization      248—253
Semiclassical quantization, matrix Hamiltonians, two-surface 1F model and surface hopping      253—259
Semiclassical quantization, mesoscopic semiconducting devices      337—341
Semiclassical quantization, molecular systems      269—272
Semiclassical quantization, molecular systems, Born — Oppenheimer Hamiltonian      269—271
Semiclassical quantization, molecular systems, Coulomb — Born — Oppenheimer Hamiltonian comparisons      272—273
Semiclassical quantization, molecular systems, rotational-vibrational Hamiltonian      271—272
Semiclassical quantization, molecular transition states      292—324
Semiclassical quantization, molecular transition states, $HgI_{2}$ system overview      293—294
Semiclassical quantization, molecular transition states, $HgI_{2}$ transition state dynamics      313—314
Semiclassical quantization, molecular transition states, ABA and ABC molecule repellers, comparison      314—316
Semiclassical quantization, molecular transition states, classical dynamics and Hamiltonian mapping      295—301
Semiclassical quantization, molecular transition states, equilibrium point quantization      301—303
Semiclassical quantization, molecular transition states, large molecule equilibrium point quantization      316—319
Semiclassical quantization, molecular transition states, nonseparable and statistical regime resonances      321—323
Semiclassical quantization, molecular transition states, periodic-orbit quantization      303—310
Semiclassical quantization, molecular transition states, rotational motion      320—321
Semiclassical quantization, molecular transition states, wavepacket propagation      310—313
Semiclassical quantization, molecular vibrograms      273—291
Semiclassical quantization, molecular vibrograms, bounded molecular systems      279—286
Semiclassical quantization, molecular vibrograms, principles      274—278
Semiclassical quantization, molecular vibrograms, unbounded molecular systems      286—291
Semiclassical quantization, observable quantities      119—123
Semiclassical quantization, observable quantities, atomic particle scattering      120—123
Semiclassical quantization, observable quantities, light interaction      119—120
Semiclassical quantization, overview      108—111
Semiclassical quantization, periodic-orbit vs. equilibrium-point techniques      345—346
Semiclassical quantization, propagator and Green operator      114—118
Semiclassical quantization, quantum billiards      227—246
Semiclassical quantization, quantum billiards, degenerate periodic orbits      234—236
Semiclassical quantization, quantum billiards, disk scattering applications      238—246
Semiclassical quantization, quantum billiards, multiple scattering expansion      228—230
Semiclassical quantization, quantum billiards, periodic orbit contribution      233—234
Semiclassical quantization, quantum billiards, stationary phase method and periodic orbits      230—232
Semiclassical quantization, quantum billiards, summation      237—238
Semiclassical quantization, quantum billiards, wave equation and generalities      227—228
Semiclassical quantization, quantum observable averages      223—227
Semiclassical quantization, quantum observable averages, diagonal matrix elements      223—226
Semiclassical quantization, quantum observable averages, photoabsorption cross section      226—227
Semiclassical quantization, quantum time evolution, path integrals and limits      114—146
Semiclassical quantization, scattering systems and chemical reaction dynamics      344—345
Semiclassical quantization, short-wavelength asymptotics, Schrodinger's equation      124—132
Semiclassical quantization, time domain, molecular vibrograms      273—291
Semiclassical quantization, time domain, propagator trace      175—190
Semiclassical quantization, time domain, propagator trace, equilibrium point continuum      179—183
Semiclassical quantization, time domain, propagator trace, harmonic oscillator examplle      187
Semiclassical quantization, time domain, propagator trace, Morse oscillator example      187—190
Semiclassical quantization, time domain, propagator trace, path integrals      178—179
Semiclassical quantization, time domain, propagator trace, periodic orbits      183—187
Semiclassical quantization, time domain, propagator trace, regularizations      175—178
Semiclassical quantization, time domain, propagator trace, short-time behavior      178
Semiclassical quantization, trace and level density      118—119
Semiclassical quantization, Weyl — Wigner representation and quasiclassical method      123—124
Semiconductor devices, historical background      113—114
Semiconductor devices, mesoscopic devices      337—341
Semisided Fourier transform, equilibrium point quantization      190—194
Semisided Fourier transform, periodic-orbit quantization      197—199
Sepulchre, J.-A.      320—321(249) 324(249) 346(249) 361
Shapere, A.      252(202) 261(202) 360
Sharfin, W.      112(32) 353
Shaw, J.      112(34) 219(34) 268—269(34) 324—325(34) 348(34) 354
Shimamura, I.      292(231) 360
Shirley, D.A.      10(72) 100
Short-time behavior, trace function of the propagator      178
Short-wavelength asymptotics, Jacobi — Hill equation and linear stability      129—131
Short-wavelength asymptotics, probability conservation and Van Vleck — Morette matrix      127—129
Short-wavelength asymptotics, semiclassical regimes      124—132
Shudo, A.      218(176) 228—229(192) 359
Sieber, M.      210(165) 344(284) 358 363
Siegbahn, K.      10(68—69) 100
Simo, C.      219(178) 359
Simon, B.      292(229) 360
Sinai billiard, trace of the propagator      186—187
Sinai billiard, wave equations      227—228
Sinai, Ya.G.      153(96) 161(96 109) 172(122) 356—357
Single-photon ionization, linear molecules      43—54
Single-photon ionization, linear molecules, carbon monoxide and nitrogen compounds      48—51
Single-photon ionization, linear molecules, HBr (2 + 1) REMPI analysis      51—53
Single-photon ionization, linear molecules, nitric oxide      43—45
Single-photon ionization, linear molecules, OH (2 + 1) REMPI analysis      53—54
Single-photon ionization, linear molecules, OH compounds      45—48
Single-photon ionization, nonlinear molecules      54—62
Single-photon ionization, nonlinear molecules, $CH_{3}$ molecules      60—62
Single-photon ionization, nonlinear molecules, $H_{2}CO$ molecules      57—60
Single-photon ionization, nonlinear molecules, water molecules      54—57
Single-well potential, periodic-orbit quantization      215—216
Sitja, G.      280—284(216—217) 345(216—217) 347(216—217) 351(305) 360 364
Sjostrand, J.      206(156) 358
Skodje, R.T.      307(241) 309(243) 360
Smale horseshoe, chaotic systems      164—170
Smale horseshoe, chaotic systems, examples      168—169
Smale horseshoe, chaotic systems, generalization of      169—170
Smale horseshoe, chaotic systems, horseshoe map      165—166
Smale horseshoe, chaotic systems, symbolic dynamics      166—168
Smale horseshoe, class chaos, periodic orbits and quantum spectra      341—344
Smale horseshoe, molecular transition state, $HgI_{2}$ experiments      292
Smale horseshoe, molecular transition state, mercuric iodide ( $HgI_{2}$ ) system      300—301
Smale horseshoe, periodic-orbit quantization, zeta function approximation      208—209
Smale horseshoe, semiclassical regimes      110
Smale, S.      164(116) 298(116) 357
Small, G.J.      87(164) 103
Smilansky, U.      109(17) 113(42) 114(48) 130(78) 136—137(78) 154(97) 161(42) 227(48) 337—338(42 48) 344(284) 349(42 290—291) 351(42) 353—354 356 363
Smith, F.T.      121—122(64) 178(64) 355
Smith, J.M.      3(6 22 35) 15(35) 63(35) 94—95(22) 98—99
Softley, T.P.      3(19 25 37) 6(19 25—26) 15—17(26) 63(9 25) 98—99
Sokolov, V.V.      323(253) 351(253) 362
Soldagi, D.      3(42) 26(42) 95(42) 99
Solgadi, D.      88(168) 103
Solid-state systems, semiclassical electronic regimes      324—341
Solid-state systems, semiclassical electronic regimes, highly excited electronic states      324—327
Solid-state systems, semiclassical electronic regimes, hydrogen negative ion      327—337
Solid-state systems, semiclassical electronic regimes, mesoscopic semiconducting devices      337—341
Solov'ev, E.A.      327(260) 362
Someda, K.      349(290) 363
Song, X.      10(76) 22(76) 87(165) 100 103
Sornette, D.      114(49) 354
Southworth, S.      10(72) 100
Spiers, M.      84(161) 103
Spin-orbit relaxation, ZEKE intensity deviations, HCl/DCl (2 + 1) threshold photoionization      64—70
Spin-orbit relaxation, ZEKE intensity deviations, OH compounds      46—48
Spirko, V.      9(65) 91—94(65) 100
Spohr, R.      11(79) 100
Springborg, M.      155(97) 187(98) 356
Srednicki, M.      351(307) 364
Stadium billiards, classical mechanics      162—163
Stadium billiards, trace of the propagator      186—187
Stadium billiards, wave equations      227—228
Staecker, J.      3(21 28) 17(21 28) 98—99
Staircase functions, periodic-orbit quantization, dynamical zeta functions      201—202
Staircase functions, periodic-orbit quantization, zero length paths      196—197
Standard mapping, phase-space structures      160

Stark mixing, ZEKE intensity deviations      63
State-to-state threshold photoionization, nitrogen dioxide      72—80
State-to-state threshold photoionization, nitrogen dioxide, rotational intensitites      76—80
State-to-state threshold photoionization, nitrogen dioxide, rotational structure      75—76
Stationary-phase integration, Feynman path integrators      134—136
Stationary-phase integration, periodic-orbit quantization      194—223
Stationary-phase integration, periodic-orbit quantization, bifurcations      222—223
Stationary-phase integration, periodic-orbit quantization, complex orbits      212—220
Stationary-phase integration, periodic-orbit quantization, dynamical zeta functions      201—211
Stationary-phase integration, periodic-orbit quantization, nonisolated orbits      220—222
Stationary-phase integration, periodic-orbit quantization, unstable-isolated orbits      197—199
Stationary-phase integration, periodic-orbit quantization, zero-length paths      195—197
Stationary-phase integration, quantum billiards      230—232
Statistical dynamics, periodic-orbit quantization      219—220
Statistical dynamics, scattering resonances, chemical reaction dynamics      345
Steadman, J.      96(186) 104
Steiger, A.      311(246) 360
Steil, G.      344(282) 363
Steiner, F.      210(165) 344(282) 358 363
Stephens, J.A.      3(44) 30(112—113) 54(135) 55(44) 99 101—102
Stephenson, T.A.      247(200) 360
Stewart, I.      223(186) 359
Stick spectrum, molecular vibrograms      274—278
Stock, G.      267(209) 360
Stokes' theorem, matrix Hamiltonians, diagonal matrices      252—253
Stone, A.D.      113(43) 161(43) 338(43) 349(43) 354
Stovneng, J.A.      121—122(64) 178(64) 355
Streets, D.G.      21(94) 84(94) 101
Strobel, A.      3(21 23 28) 17(21 23 28) 98—99
Strunz, W.T.      212(172) 214(172) 359
Stueckelberg, E.G.C.      247(201) 251(201) 348(201) 360
Sturm — Liouville problem, Feynman path integrators, Jacobi — Hill equation and linear stability      130—131
Sturm — Liouville problem, Feynman path integrators, second variation and Jacobi — Hill equation      136—139
Sudden approximation, rotationally resolved ZEKE spectra      19
Superadiabatic levels, matrix Hamiltonians      247
Surface electron motion, semiclassical regimes      113—114
Surface hopping, h-expansion and anharmonicity      348—349
Surface hopping, matrix Hamiltonians      247
Surface hopping, matrix Hamiltonians, two-surface one-degree-of-freedom model      253—259
Suto, M.      290(225) 360
Swimm, R.T.      194(143) 358
Syage, J.A.      96(186) 104
Symbolic dynamics, Smale horseshoe      164—170
Symbolic dynamics, Smale horseshoe, examples      168—169
Symbolic dynamics, Smale horseshoe, generalization of      169—170
Symbolic dynamics, Smale horseshoe, horseshoe map      165—166
Symmetric tops, (n + 1') REMPI process      40—41
Symmetry selection rules, ZEKE analysis      5
Symmetry-forbidden transitions      7
Szebehely, V.      331(264) 362
Szepfalusy, P.      173—174(126) 357
Szeredi, T.      209(163) 358
Tabanov, M.B.      219(178) 359
Tabor, M.      159(104) 219(104) 220—221(180) 345(180) 356 359
Takahashi, M.      8(63) 47(131) 100 102
Tanner, G.      111(23) 156(99—100) 169(99—100) 206(159) 209(163) 210(167—168) 268(23 100) 325(23 99—100) 326(99—100) 327—328(23 99—100) 331(99) 353 356 358—359
Tapper, R.S.      71(151) 103
Taylor expansion, Feynman path integrators      141—145
Taylor expansion, molecular transition state      306—307
Taylor expansion, periodic-orbit quantization, quantum billiards      233—234
Taylor expansion, periodic-orbit quantization, stationary-phase integration      198—199
Taylor expansion, trace of the propagator, equilibrium points      181—183
Taylor expansion, trace of the propagator, periodic orbits      183—187
Taylor, H.S.      307(240) 360
Tel, T.      173—174(126) 357
Teller, E.      4(54) 21(54) 99
Terenin, A.N.      10—11(67) 100
Tersigni, S.H.      160(105) 356
Teukolsky, S.A.      304(245) 360
Thermal reaction rates, periodic-orbit quantization      219—220
Thermodynamic formalism, phase-space structures      170—175
Thirring, W.      118(58) 121(64) 122(58 64) 178(58 64) 355
Thomas — Fermi — Weyl — Wigner average level density, Feynman path integrators, Jacobi — Hill equation      138—139
Thomas — Fermi — Weyl — Wigner average level density, semiclassical regimes      123—142
Thomas — Fermi — Weyl — Wigner average level density, short-time behavior      178
Thomas, L.H.      112(30) 268(30) 353
Thomas, R.G.      241(194) 292(231) 322(194) 360
Three-branch horseshoe, scattering resonances      344—345
Three-color triple-resonant threshold photoionization      70—83
Three-color triple-resonant threshold photoionization, electronic structure and photoselection      71—72
Three-color triple-resonant threshold photoionization, vibrational relaxation, threshold intensities      80—83
Three-color triple-resonant threshold photoionization, vibrational structure and state-to-state photoionization      72—80
Three-disk scatterer, molecular transition state      321—324
Threshold photoelectron spectroscopy (TPES), origins of ZEKE and      11
Threshold photoelectron spectroscopy (TPES), ZEKE intensity deviations and      62—63
Threshold photoionization      see also "Delayed pulsed-field threshold photoionization" "State-to-state
Thurwachter, R.      327(260) 362
Tiller, A.R.      247(200) 360
Time domain, h-expansion, equilibrium points      179—183
Time domain, h-expansion, harmonic oscillator      187
Time domain, h-expansion, Morse oscillator      187—190
Time domain, h-expansion, path integral      178—179
Time domain, h-expansion, periodic orbits      183—187
Time domain, h-expansion, propagator trace formula      175—190
Time domain, h-expansion, regularization      175—178
Time domain, h-expansion, short-time behavior      178
Time domain, molecular vibrograms      274—278
Time domain, molecular vibrograms, basic principles      274—278
Time domain, molecular vibrograms, bounded systems      279—286
Time domain, molecular vibrograms, unbounded systems      286—291
Time domain, periodic-orbit vs. equilibrium point quantization      346
Time domain, semiclassical regimes      114—146
Time domain, semiclassical regimes, atomic particle scattering      121—122
Time domain, semiclassical regimes, Feynman path integrators      133—145
Time domain, semiclassical regimes, Feynman path integrators, stationary-phase integration      134—136
Time domain, semiclassical regimes, overview      110
Time domain, semiclassical regimes, propagator and Green operator      114—118
Time-of-flight (TOF) measurements, field ionization of Rydberg states      18—19
Time-of-flight (TOF) measurements, rotationally resolved ZEKE spectra      21—22
Time-of-flight (TOF) measurements, vs. photoionization efficienty (PIE) measurements      6—7
Time-of-flight (TOF) measurements, Zeke Rydberg states      15—16
Tomoda, S.      89(170) 103
Tomsovic, S.      120(61) 162(61) 290(61) 312(61) 351(308) 355 364
Tonkyn, R.G.      3(13 30—32) 17(13) 30(13 114 140) 45(130) 47(30 130 140) 48—49(140) 54(31) 55—57(32) 62(140) 63(30 140) 80(30 140) 98—99 101—102
Topological pressures, periodic-orbit quantization, Ruelle zeta function      205—206
Topological pressures, phase-space structures, thermodynamic formalism      172—175
Toriyama, K.      5(57) 21(57) 99
Trace formula, propagators, path integral      178—179
Trace formula, propagators, regularizations      175—178
Trace formula, propagators, short-time behavior      178
Trace formula, semiclassical regimes      109—111
Trajectory conditions, molecular transition state      295—296
Tramer, A.      88(168) 103
Transfer operator, periodic-orbit quantization, 1F system tunneling      212—218
Transfer operator, periodic-orbit quantization, zeta function approximation      206—209
Transition state      see "Molecular transition state"
Transmission matrix, mesoscopic semiconducting devices      337—341
Trapped trajectories, phase-space structures      154
Tromp, J.W.      219—220(179) 359
Truesdale, C.M.      10(72) 100
Truhlar, D.G.      252—253(203) 309(243) 351(300) 360 363
Turchetti, G.      173—174(126) 357
Turner, D.W.      3(52) 10—11(52 66) 84(52) 99—100
Turner, J.-W.      245(196) 360
Two-channel scattering map, phase-space structures      161
Two-color photoionization efficiency (REMPI-PIE), phenol-water cations      89—91
Two-color photoionization efficiency (REMPI-PIE), zero-kinetic-energy (ZEKE) photoelectron techniques      16—17
Two-degree-of-freedom systems, bounded molecular models      283—284
Two-degree-of-freedom systems, molecular transition state      303—307
Two-degree-of-freedom systems, periodic-orbit quantization      218—219
Two-electron atomic systems, phase-space structure      156—157
Two-electron atomic systems, symbolic dynamics      169
Tworkowski, A.S.      326(256) 362
Ullmo, D.      340(278) 362
Ultraviolet absorption spectra, carbon dioxide molecules      286—290
Ultraviolet absorption spectra, unbounded molecular systems      286—291
Ultraviolet photoelectron spectroscopy      89
Unbounded molecular systems, vibrograms      286—291
Unbounded molecular systems, vibrograms, carbon dioxide molecules      286—290
Unbounded molecular systems, vibrograms, hydrogen sulfide and deuterium sulfide molecules      290—291

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