Shen Y.R. — The Principles of Nonlinear Optics :: 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

Shen Y.R. — The Principles of Nonlinear Optics

Обсудите книгу на научном форуме

Нашли опечатку?
Выделите ее мышкой и нажмите Ctrl+Enter

Название: The Principles of Nonlinear Optics

Автор: Shen Y.R.

Аннотация:

A comprehensive treatment of nonlinear optics emphasizing physical concepts and the relationship between theory and experiment. Systematically describes a number of sub-topics in the field. Up-to-date references and numerous illustrations will help both beginners and practitioners interested in gaining a more thorough understanding of the subject.

Язык:

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Год издания: 1984

Количество страниц: 563

Добавлена в каталог: 20.03.2008

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

Предметный указатель

Acoustic wave equation      290
Adiabatic following      399—401
Adiabatic inversion      400
Anharmonic oscillator      5—8 439
Anomalies in stimulated Raman scattering      159 316—319
Anomalies in stimulated Raman scattering due to self-focusing      159 316—319
Anomalies in stimulated Raman scattering, anti-Stokes rings      159 319
Anomalies in stimulated Raman scattering, effective Raman gain      159 316
Anomalies in stimulated Raman scattering, forward-backward asymmetry      158—159 318
Anti-Stokes Raman scattering, spontaneous      168—169
Anti-Stokes Raman scattering, stimulated      167—168
Applications of stimulated Raman scattering, high-resolution spectroscopy      167—169
Applications of stimulated Raman scattering, tunable infrared sources      164—167
Applications of stimulated Raman scattering, tunable UV sources      167—169
Approximation, slow varying amplitude      47—49
Autler — Townes effect      418 425 429—430
Autoionization spectroscopy      346—347
Backward parametric amplification and oscillation      248—249
Bare atom      415—421
Bare atom, three-level system      418—421
Bare atom, two-level system      416—418
Bistability, optical      299—301
Blackbody radiation      108
Bloch equation      379—383
Bloch equation in rotating frame      382
Bloch equation, pseudo-dipole in      382
Bond model for calculations of susceptibilities      29—31
Bond model for calculations of susceptibilities, addivitivity rule      30
Bond model for calculations of susceptibilities, bond polarizabilities      30
Breakdown, DC or microwave      529
Breakdown, dependence on gas pressure      534
Breakdown, laser-induced thermal      529 537
Breakdown, optical      528—540
Breakdown, similarity principle for      532
Brillouin doublet      192
Brillouin scattering, stimulated      187—192
Broadening of spectral line      211—213
Broadening of spectral line, collisional      213
Broadening of spectral line, Doppler      212
Broadening of spectral line, homogeneous      212—213
Broadening of spectral line, inhomogeneous      212
Broadening of spectral line, power      213
Broadening of spectral line, pressure      213
Cherenkov radiation      200 314
Coherent anti-Stokes Raman scattering (CARS)      267—272
Coherent anti-Stokes Raman scattering (CARS), applications      270—271
Coherent anti-Stokes Raman scattering (CARS), experimental arrangement      271
Coherent anti-Stokes Raman scattering (CARS), nonresonant background      268—270
Coherent anti-Stokes Raman scattering (CARS), signal strength      270
Coherent anti-Stokes Raman scattering (CARS), spectrum      268—269
Coherent anti-Stokes Raman scattering (CARS), surface      491—493
Coherent length      76
Coherent Raman spectroscopy      267—275
Coherent Raman spectroscopy of excited states      280—281
Coherent Raman spectroscopy, pressure-induced      281
Coherent Stokes Raman scattering      275
Coherent transient effects      see “Transient coherent optical effects”
Compression of ultrashort pulses      524—526
Compression of ultrashort pulses, experimental arrangement      524
Cotton — Mouton effect      55
Cotton — Mouton effect, inverse      60—66
Coupled-wave approach      see “Stimulated Raman scattering”
Coupled-wave approach, boundary conditions      50
Coupled-wave approach, energy and momentum conservation      44
Coupled-wave approach, energy transfer among waves      44
Coupled-wave approach, phase matching condition      44
Coupled-wave approach, slowly varying amplitude approximation      47—49
Debye equation      198 298 319
Debye relaxation      198
Degenerate four-wave mixing      249—251
Degenerate four-wave mixing, connection with holography      250
Degenerate four-wave mixing, polarization dependence      250—251
Degenerate four-wave mixing, symmetry consideration      250
Density matrix formalism      13—17 415—419
Density matrix formalism for transient four-wave mixing      259—262 393—395
Density variation, laser-induced      290
Detection of rare atoms and molecules      270—271 275 349—365
Detection of rare atoms and molecules, applications      363—364
Detection of rare atoms and molecules, basic theory      349—354
Detection of rare atoms and molecules, conditions      352
Detection of rare atoms and molecules, demonstrations      360—363
Detection of rare atoms and molecules, experimental techniques      354—360
Detection of rare atoms and molecules, laser-induced fluorescence      354—358
Detection of rare atoms and molecules, photoioni24tion      358—360
Detection of rare atoms and molecules, requirement      349—350
Detection of rare atoms and molecules, signal-to-background ratio (discrimination factor)      352—354
Difference frequency generation      108—116
Difference frequency generation of far-infrared radiation      110—116
Difference frequency generation of tunable infrared radiation      109
Doppler broadening      212
Doppler-free spectroscopy, coherent transient spectroscopy      see “Transient coherent optical effects”
Doppler-free spectroscopy, four-wave mixing spectroscopy      277—279
Doppler-free spectroscopy, multiphoton absorption and saturation spectroscopy      240
Doppler-free spectroscopy, polarization spectroscopy      232—235
Doppler-free spectroscopy, saturation spectroscopy      216—229
Doppler-free spectroscopy, two-photon absorption spectroscopy      229—232
Dressed atom      220 421—425
Dressed atom, absorption and fluorescence spectra      423
Dressed atom, effective n-level system      425
Dressed atom, three-level system      424—125
Dressed atom, two-level system      421—424
Dynamic (AC) Stark splitting      220 (see also “Optical Stark effect”)
Electron multiplication      531
Electrooptical effects      53—54
Electrooptical effects, DC Kerr effect      54
Electrooptical effects, Pocket’s effect      53
Energy randomization      458—459
Energy relation for fields      44—47
Exciton molecules      208
Exciton polaritons      207—208
Fabry — Perot interferometer, nonlinear      299—301
Far-infrared generation by difference-frequency mixing      110—116 176
Far-infrared generation by difference-frequency mixing, absorption      112
Far-infrared generation by difference-frequency mixing, diffraction effect      111—112
Far-infrared generation by difference-frequency mixing, phase matching effect      112
Far-infrared generation by difference-frequency mixing, reflection at boundary      112
Far-infrared generation by difference-frequency mixing, total reflection      112
Far-infrared generation by ultrashort pulses      113—116
Far-infrared generation by ultrashort pulses, power spectrum      114—115
Faraday effect, inverse      61—66
Faraday rotation      55
Feynman diagram, double      19—23 259—261 393—397
Field energy in nonlinear medium      46—47
Field energy, effective density      59—60
Field energy, energy density      46—47
Field energy, time-average conservation relation      47
Filament formation in CW self-focusing      323—324
Filament formation in quasi-steady-state self-focusing      315
Filament formation in self-focusing in plasmas      553
Filament formation in transient self-focusing      320—321
Fluorescence, multiphoton-induced spectroscopy      337 (see also “Laser-induced fluorescence”)
Forced light scattering      281—282
Four-wave mixing      242—265
Four-wave mixing in optical fibers      513
Four-wave mixing in plasma      547
Four-wave mixing spectroscopy      266—285
Four-wave mixing spectroscopy as high-resolution Doppler-free spectroscopy      277—279
Four-wave mixing spectroscopy, coherent anti-Stakes Raman spectroscopy (CARS)      267—272
Four-wave mixing spectroscopy, coherent Raman spectroscopy      267—275
Four-wave mixing spectroscopy, forced light scattering spectroscopy      281—282
Four-wave mixing spectroscopy, general description      266—267
Four-wave mixing spectroscopy, multiply resonant spectroscopy      277—281
Four-wave mixing spectroscopy, polarization CARS      272—275
Four-wave mixing spectroscopy, Raman-induced Kerr effect spectroscopy      275—277
Four-wave mixing spectroscopy, resonant characteristics in      266—267
Four-wave mixing spectroscopy, transient      283
Four-wave mixing with output in same mode as input field      248
Four-wave mixing with three pump fields      247—248
Four-wave mixing, backward parametric process      248—249
Four-wave mixing, degenerate      249—251

Four-wave mixing, general theory      247—249
Four-wave mixing, nonlinear susceptibilities for      242—247
Four-wave mixing, phase conjugation      251—254
Four-wave mixing, pressure-induced extra resonance (PIER)      281
Four-wave mixing, spectroscopy      266—285 (see also “Four-wave mixing spectroscopy”)
Four-wave mixing, transient      259—264 (see also “Transient four-ware mixing”)
Four-wave mixing, tunable infrared and uv generation by      254—259
Free electron gas      8—11
Hamilton — Jacobi equation      308
Harmonic generation      86—116
Harmonic generation in plasmas      548—550
High-resolution nonlinear optical spectroscopy      211—241
High-resolution Raman spectroscopy      167—169 270
Hole burning      218—222
Index ellipsoid      54
Infrared multiphoton excitation and dissociation of molecules      437—465
Infrared multiphoton excitation and dissociation of molecules, early investigations      437—441
Infrared multiphoton excitation and dissociation of molecules, experimental results      453—458
Infrared multiphoton excitation and dissociation of molecules, models      446—453 459—461
Infrared multiphoton excitation and dissociation of molecules, physical description      441—446
Infrared-to-visible converter      256
Inhomogeneous broadening      211—212
Intensity-dependent ellipse rotation      295—296
Intensity-dependent ellipse rotation, experimental arrangement      296
Interference between Raman and two-photon resonances      275
Inverse Bremstrahlung process      529
Inverse Faraday and Cotton — Motion effect      60—66
Ionization, cascade or avalanche      529 532
Ionization, electron-impact      529
Ionization, multiphoton      337—339 528—529 533
Ionization, single-atom      528
Ionization, threshold rate      531
Isotope enrichment factor      438 469
Isotope separation      374 438 466—478
Isotope shifts      466—467
Isotope shifts, hyperfine interaction      467
Isotope shifts, mass effect      466—467
Isotope shifts, volume shift      467
Jacobi elliptical integral      80
Jacobian      104
Lamb dip      225—226
Lamb dip, inverted      226—227
Lamb shift      223—224
Laser fusion      271 350 552 278—279
Laser isotope separation      466—478
Laser isotope separation by infrared multiphoton dissociation      476
Laser isotope separation by one-step photopredissociation      474—475
Laser isotope separation by photochemical methods      473—476
Laser isotope separation by photochemical reaction      473—474
Laser isotope separation by photodeflection      240 471—473
Laser isotope separation by photoionization      470—471
Laser isotope separation by photophysical methods      470—473
Laser isotope separation by two-step photodissociation and photopredissociation      475—476
Laser isotope separation of $ortho-I_{2}$       473
Laser isotope separation of B      476
Laser isotope separation of Ba      471—472
Laser isotope separation of hydrogen/deuterium      473 475
Laser isotope separation of uranium      462 470—471 476
Laser isotope separation, based on atomic excitation      469
Laser isotope separation, based on molecular excitation      469
Laser isotope separation, basic requirement      468
Laser isotope separation, general description      466—469
Laser manipulation of particles      366—378
Laser steering of atomic beams      373—375
Laser steering of atomic beams for isotope separation      374
Laser steering of atomic beams, deceleration of atoms      374
Laser steering of atomic beams, deflection of atomic beam      374
Laser steering of atomic beams, experimental arrangement      374
Laser steering of atomic beams, focusing of atomic beam      374—375
Laser-induced fluorescence      229 354—358 457
Laser-induced fluorescence for detection of rare atoms and molecules      354 357
Laser-induced fluorescence, coincidence counting technique      356
Laser-induced fluorescence, experimental arrangement      356—357
Liouville’s equation      14 380 416 419
Liquid crystals      293
Magneto-optical effects      54—56
Magneto-optical effects, Cotton — Mouton effect      55
Magneto-optical effects, Faraday effect      55
Magneto-optical effects, inverse effects      60—66
Maker fringes      99—100
Manley — Rowe relation      78
Maxwell equations      2—3
Maxwellian velocity distribution      212
Measurement of nonlinear optical susceptibilities      98—103
Measurement of nonlinear optical susceptibilities, interference method      99—100
Measurement of nonlinear optical susceptibilities, phase factor      99—100
Measurement of nonlinear optical susceptibilities, powder method      102—103
Molecular redistribution      95 291 293
Molecular reorientation      195—198
Molecular reorientation by circularly polarized field      292
Molecular reorientation by linearly polarized field      292
Molecular reorientation in liquid crystalline media      293
Molecular reorientation, optical-field-induced      195—198 291—293
Multichannel quantum defect theory      340
Multiphoton dissociation, infrared, analog model      459—461
Multiphoton dissociation, infrared, bond-selective (or mode selective)      440 461—462
Multiphoton dissociation, infrared, competing dissociation channels      458
Multiphoton dissociation, infrared, critical configuration      448
Multiphoton dissociation, infrared, dependence on laser intensity and fluence      452
Multiphoton dissociation, infrared, dissociation channels      440 445 453 458 462
Multiphoton dissociation, infrared, dissociation lifetime      448
Multiphoton dissociation, infrared, dissociation rate      448
Multiphoton dissociation, infrared, dissociation states      448
Multiphoton dissociation, infrared, dynamics      440 457
Multiphoton dissociation, infrared, excess energy      445 452 457
Multiphoton dissociation, infrared, exit energy barrier      448 457
Multiphoton dissociation, infrared, in continuum      445—446
Multiphoton dissociation, infrared, isotopically selective      438
Multiphoton dissociation, infrared, products      440
Multiphoton dissociation, infrared, secondary dissociation      453 458 462
Multiphoton dissociation, infrared, simple model      446—453
Multiphoton dissociation, infrared, summary      461—463
Multiphoton dissociation, infrared, two-laser scheme      454
Multiphoton dissociation, infrared, yields      439
Multiphoton excitation      354 432—435 539
Multiphoton excitation, infrared      437—465
Multiphoton excitation, infrared, as laser heating process      445
Multiphoton excitation, infrared, average excitation level      456
Multiphoton excitation, infrared, coherent effect in      462
Multiphoton excitation, infrared, in true continuum      445—446
Multiphoton excitation, infrared, induced luminescence      437—438
Multiphoton excitation, infrared, isotopically selective      438
Multiphoton excitation, infrared, limited by dissociation      445
Multiphoton excitation, infrared, population distribution after      449—451
Multiphoton excitation, infrared, stepwise resonant or near-resonant      441—442
Multiphoton excitation, infrared, through discrete levels      441—443
Multiphoton excitation, infrared, through quasi-continuum      443—445
Multiphoton ionization      528—529 533
Multiphoton ionization, spectroscopy      337—339
Multiphoton spectroscopy      334—348
Multiphoton spectroscopy, Doppler-free      336
Multiphoton spectroscopy, experimental techniques      337—339
Multiphoton spectroscopy, general considerations      334—336
Multiphoton transitions      334—336
Multiphoton transitions, (m+1)-step n-photon transition      336
Multiphoton transitions, detection      337—339
Multiphoton transitions, n-th order perturbation calculation      335
Multiphoton transitions, population excitation      334—335
Multiphoton transitions, single-step n-photon transition      33
Multiphoton transitions, transition probability      334
Multiphoton-induced fluorescence      337
Multiply resonant four-wave mixing      227—281
Multiply resonant four-wave mixing as Doppler-free spectroscopy      227—279
Multiply resonant four-wave mixing, coherent Raman spectroscopy of excited states      280—281
Multiply resonant four-wave mixing, doubly resonant case      244—245 278—279
Multiply resonant four-wave mixing, measurement of longitudinal relaxation time      279—280
Multiply resonant four-wave mixing, triply resonant case      245—246 275
Multipoles      3
Navier — Stokes equation      192
Nonlinear optical effect in optical waveguides      505—527

1 2 3

О проекте