Shen Y.R. — The Principles of Nonlinear Optics :: Электронная библиотека попечительского совета мехмата МГУ

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Shen Y.R. — The Principles of Nonlinear Optics

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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

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Год издания: 1984

Количество страниц: 563

Добавлена в каталог: 20.03.2008

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Предметный указатель

Nonlinear optical effect in optical waveguides in optical fibers      510—517
Nonlinear optical effect in optical waveguides in thin-film waveguides      509—510
Nonlinear optical effect in optical waveguides, effective interaction length      507 511
Nonlinear optical effect in optical waveguides, four-wave mixing      507 513
Nonlinear optical effect in optical waveguides, four-wave parametric amplification      507—509 515
Nonlinear optical effect in optical waveguides, general theory      505—509
Nonlinear optical effect in optical waveguides, optical field-induced refractive index change      515 518—519
Nonlinear optical effect in optical waveguides, optical Kerr effect      515
Nonlinear optical effect in optical waveguides, phase matching condition      510
Nonlinear optical effect in optical waveguides, second harmonic generation      509 510
Nonlinear optical effect in optical waveguides, self-phase modulation      515—517
Nonlinear optical effect in optical waveguides, spectral broadening      515—516
Nonlinear optical effect in optical waveguides, stimulated Raman and Brillouin scattering      507 511—515
Nonlinear optical effect in optical waveguides, wave interaction      506
Nonlinear optical effect in plasmas      541—554
Nonlinear optical effect in plasmas, basic formalism      8—11 542—548
Nonlinear optical effect in plasmas, coupling of light with plasma waves      543—548
Nonlinear optical effect in plasmas, experimental studies      548—553
Nonlinear optical effect in plasmas, four-wave mixing      552
Nonlinear optical effect in plasmas, harmonic generation      548—550
Nonlinear optical effect in plasmas, optical nonlinearities      8—10 542—543
Nonlinear optical effect in plasmas, optical-field-induced refractive index change      547—548 553
Nonlinear optical effect in plasmas, parametric instabilities      547 552
Nonlinear optical effect in plasmas, second harmonic generation      10—11 543 548
Nonlinear optical effect in plasmas, self-focusing      548 553
Nonlinear optical effect in plasmas, self-phase modulation      548 553
Nonlinear optical effect in plasmas, stimulated Raman and Brillouin scattering      545—547 549 551—552
Nonlinear optical effects as surface probes      493—503
Nonlinear optical effects as surface probes, second harmonic generation      495—503
Nonlinear optical effects as surface probes, stimulated Raman gain spectroscopy      494
Nonlinear optical effects as surface probes, surface CARS      494
Nonlinear optical effects involving surface electromagnetic waves      481—493
Nonlinear optical effects involving surface electromagnetic waves at plane boundary      486—488
Nonlinear optical effects involving surface electromagnetic waves, experimental setup      489 492
Nonlinear optical effects involving surface electromagnetic waves, generation of bulk wave      487—438
Nonlinear optical effects involving surface electromagnetic waves, generation of surface wave      438—493
Nonlinear optical effects involving surface electromagnetic waves, phase matching      491
Nonlinear optical effects involving surface electromagnetic waves, second harmonic generation      488
Nonlinear optical effects involving surface electromagnetic waves, surface CARS      491—493
Nonlinear optical effects involving surface electromagnetic waves, surface wave excitation by optical mixing      488—493
Nonlinear optical susceptibilities      13—41
Nonlinear optical susceptibilities for molecular crystals      37
Nonlinear optical susceptibilities, bond model      30—36
Nonlinear optical susceptibilities, bond-charge model      33—34
Nonlinear optical susceptibilities, bull      480 497
Nonlinear optical susceptibilities, charge transfer model      34
Nonlinear optical susceptibilities, conventions on      38—40
Nonlinear optical susceptibilities, diagrammatic technique for calculation      19—23
Nonlinear optical susceptibilities, empirical pseudopotential calculation      36
Nonlinear optical susceptibilities, Kleinman’s conjecture on      26
Nonlinear optical susceptibilities, LCAO methods      37
Nonlinear optical susceptibilities, local field correction      23—25
Nonlinear optical susceptibilities, measurement of      98—103
Nonlinear optical susceptibilities, microscopic expressions for      17—19
Nonlinear optical susceptibilities, Miller’s coefficient      37—38
Nonlinear optical susceptibilities, permutation symmetry      25—26 57
Nonlinear optical susceptibilities, perturbation calculation      16—19
Nonlinear optical susceptibilities, phase factor      99—100
Nonlinear optical susceptibilities, practical calculations      29—37
Nonlinear optical susceptibilities, semiempirical Hartree — Fock method      37
Nonlinear optical susceptibilities, structural symmetry      26—29
Nonlinear optical susceptibilities, surface      480 497—498
Nonlinear optical susceptibilities, tables      27 28 101
Nonlinear Schrodinger’s equations      518
Optical breakdown      528—540
Optical breakdown in gases      530—536
Optical breakdown in solids      536—539
Optical breakdown on surfaces      539
Optical breakdown, general description      528—530
Optical breakdown, initiation      530—531
Optical breakdown, self-focusing effect      530 537
Optical breakdown, statistical nature      533 538
Optical breakdown, threshold      531—537
Optical breakdown, threshold, apparent      530 536
Optical breakdown, threshold, intrinsic      530
Optical cooling of atoms      375—376
Optical Kerr effect      294—296 518—519
Optical Kerr effect as four-wave mixing      295
Optical Kerr effect in optical fibers      518—519
Optical Kerr effect, experimental arrangement      295
Optical levitation      317—373
Optical levitation, applications      372—373
Optical levitation, experimental setup      372
Optical Ramsey fringes      235—240
Optical Ramsey fringes with two-photon transition in two-level system      237—240
Optical Ramsey fringes, experimental arrangement      235 238—239
Optical rectification      57—66
Optical rectification, inverse magneto-optical effect      60—66
Optical Stark effect      61 414 425
Optical trapping of atoms and ions      376—377
Optical-field-induced refractive index change (optical-field-induced birefringence)      286—302
Optical-field-induced refractive index change (optical-field-induced birefringence) in absorbing medium      293
Optical-field-induced refractive index change (optical-field-induced birefringence) in atomic vapor      289
Optical-field-induced refractive index change (optical-field-induced birefringence) in mixture      293
Optical-field-induced refractive index change (optical-field-induced birefringence) in optical fibers      515 518—519
Optical-field-induced refractive index change (optical-field-induced birefringence) in photorefractive materials      293
Optical-field-induced refractive index change (optical-field-induced birefringence) in plasmas      547—548 553
Optical-field-induced refractive index change (optical-field-induced birefringence), applications      298—301
Optical-field-induced refractive index change (optical-field-induced birefringence), electronic contribution      287—289 297
Optical-field-induced refractive index change (optical-field-induced birefringence), electrostriction      290—291 297
Optical-field-induced refractive index change (optical-field-induced birefringence), general form      286—287
Optical-field-induced refractive index change (optical-field-induced birefringence), measurements of      294—297
Optical-field-induced refractive index change (optical-field-induced birefringence), molecular reorientation and redistribution      291—293 298
Optical-field-induced refractive index change (optical-field-induced birefringence), physical mechanisms      287—294
Optical-field-induced refractive index change (optical-field-induced birefringence), population redistribution      288
Optical-field-induced refractive index change (optical-field-induced birefringence), Raman-induced      289—290
Optical-field-induced refractive index change (optical-field-induced birefringence), saturation effect      288—289
Optical-field-induced refractive index change (optical-field-induced birefringence), transient effect      297—298
Orientational distribution function      197
Orientational order parameter      197 291
Parametric amplification      117—119
Parametric amplification vs. difference-frequency generation      118
Parametric amplification, high-conversion limit      119
Parametric amplification, signal and idler waves      118
Parametric coupling between, light and acoustic and entropy waves      192
Parametric coupling between, light and acoustic waves      187
Parametric coupling between, light and concentration variation      199
Parametric coupling between, light and material excitation      148—151
Parametric coupling between, light and molecular orientation      198
Parametric fluorescence (or scattering)      134—135
Parametric four-wave mixing      153
Parametric four-wave mixing in optical fibers      507—509 515
Parametric instabilities      547 552
Parametric oscillator      120—134
Parametric oscillator, backward      138—139
Parametric oscillator, conversion efficiency      124 127
Parametric oscillator, doubly resonant      120—124
Parametric oscillator, frequency tuning      127—134
Parametric oscillator, power output      124 127
Parametric oscillator, singly resonant      124—127
Parametric oscillator, stability      122—123 124
Parametric oscillator, threshold      122 125—126
Parametric superfluorescence      136—138
Parametric superfluorescence as tunable picosecond infrared source      138
Parametric superfluorescence, bandwidth      138
Parametric superfluorescence, output power      137
Phase conjugation      251—254
Phase conjugation from stimulated light scattering      254
Phase conjugation, applications      254
Phase conjugation, collection of aberration      251—253
Phase matching, Type I and Type II      76
Photoionization      358—360
Photon echoes      388—399
Photon echoes, backward and forward echoes      398—399
Photon echoes, conditions for      389 396—398
Photon echoes, multi-level system with multi-pulse excitations      392 399
Photon echoes, other echoes      399
Photon echoes, phase matching requirement      391
Photon echoes, quantitative analysis      391
Plasma dispersion function      278

Plasma formation, laser-induced      528—531
Plasma formation, laser-induced, by electron avalanche      529
Plasma formation, laser-induced, hydrodynamic expansion      529
Plasma formation, laser-induced, primary electrons for      530 531 537
Plasma formation, laser-induced, threshold laser intensity      531—533
Plasma resonance      11
Plasma waves      543—547
Plasma waves, dispersion curve      544
Plasma waves, electron (or optical)      544
Plasma waves, ion-acoustic      544
Plasma waves, resonant frequencies      544
Plasmas, laser-heating of      541 551—552
Plasmas, laser-induced      548 552—553
Plasmas, two-component (electron-ion)      542
Polariton dispersion curve      170
Polarization CARS      272—275
Polarization CARS as heterodyne technique      274
Polarization CARS, experimental arrangement      273
Polarization CARS, suppression of nonresonant background      273—274
Polarization labelling spectroscopy      232—235
Polarization spectroscopy, CARS      272—275
Polarization spectroscopy, high-resolution      232—235
Polarization spectroscopy, labelling      232—235
Polarization spectroscopy, Raman-induced Kerr effect      275—277
Preionization      531—533
Pressure-induced extra resonance in four-wave mixing (PIER-4)      281
Pulse propagation in fiber      517—526
Pulse propagation in fiber, effect of field-induced refractive index      518
Pulse propagation in fiber, effect of group velocity dispersion      518
Pulse propagation in fiber, formal description      518—519
Pulse propagation in fiber, pulse broadening      519
Pulse propagation in fiber, pulse compression      523—526
Pulse propagation in fiber, pulse narrowing      519—522
Pulse propagation in fiber, solitons      519—524
Quantum beats      213—216
Quasi-coutinuum states of molecule      429 443—445 453—456
Rabi frequency      384 418 421
Radiation forces      366—371
Radiation forces, dipole force      369—370 374 376—377
Radiation forces, electrostrictive force      188 367
Radiation forces, radiation pressure force      368—369
Radiation forces, scattering force      370 376—377
Raman gain and inverse Raman spectroscopy      167—169 275
Raman scattering, stimulated      see “Stimulated”
Raman susceptibilities      147
Raman susceptibilities, microscopic expression      147
Raman susceptibilities, relation with differential Raman cross-section      147
Raman susceptibilities, relation with Raman gain      147
Raman susceptibilities, relation with Raman transition probabilities      147
Raman transitions between excited states      280—281
Raman-induced Kerr effect      275—277 289
Raman-induced Kerr effect, induced birefringence      276 289
Raman-induced Kerr effect, spectroscopy      275—277
Raman-induced Kerr effect, suppression of nonresonant background      276—277
Ramsey fringes      233—240
Rayleigh component      192
Rayleigh scattering, stimulated      194
Rayleigh scattering, stimulated, thermal      192—195
Rayleigh-wing scattering, stimulated      195—199
Relaxation      15
Relaxation times      15 181—184
Relaxation, longitudinal (population)      15
Relaxation, transverse (dephasing)      15
RRKM model      448—450 459
Rydberg atoms      340—346
Rydberg atoms, diamagnetic effect      342—343
Rydberg atoms, exhibiting amplified spontaneous emission      345
Rydberg atoms, exhibiting maser action      345—346
Rydberg atoms, experimental setup      342
Rydberg atoms, fine structure splittings      340 341 344
Rydberg atoms, ionization      344
Rydberg atoms, linewidth vs. principal quantum number      341
Rydberg atoms, pressure shifts and pressure broadening      341
Rydberg atoms, properties of      341
Rydberg atoms, transition probabilities      343
Rydberg atoms, two-photon Doppler-free spectra      341
Rydberg spectrometer      344
Saturation Raman spectroscopy      275
Saturation spectroscopy      216—229
Saturation spectroscopy in multi-level system      227—229
Saturation spectroscopy in two-level system      216—227
Saturation spectroscopy, coherent effect      220 221—223
Saturation spectroscopy, copropagating pump and probe      218—220
Saturation spectroscopy, counter-propagating pump and probe      220—227
Saturation spectroscopy, experimental arrangement      223
Saturation spectroscopy, saturation effect      217
Saturation spectroscopy, two counter-propagating beams of equal intensity      225—227
Saturation spectroscopy, weak probe and strong pump      218—222
Saturation spectroscopy, weak saturation limit      217 221
Second-harmonic generation      1 86—93
Second-harmonic generation as surface probe      495—503
Second-harmonic generation as surface probe, between media with inversion symmetry      495
Second-harmonic generation as surface probe, effective surface nonlinear susceptibility      496—497
Second-harmonic generation as surface probe, experimental arrangement      498
Second-harmonic generation as surface probe, sensitivity      499—501
Second-harmonic generation as surface probe, signal strength      497—498
Second-harmonic generation as surface probe, studying submonolayer adsorbates      499—503
Second-harmonic generation as surface probe, surface vs. bulk contribution      497
Second-harmonic generation in plasma      10—11 543 548
Second-harmonic generation in waveguides      509 510
Second-harmonic generation with $90^{\circ}$ -phase matching      89 90
Second-harmonic generation with focused Gaussian beam      89—93
Second-harmonic generation with surface waves      488
Second-harmonic generation with ultrashort pulses      103—106
Second-harmonic generation, collinear phase matching      88—89
Second-harmonic generation, double refraction effect      90—92
Second-harmonic generation, effective length      91
Second-harmonic generation, efficiency      88 90 92
Second-harmonic generation, optimum focusing      91—93
Second-harmonic generation, output power      86
Second-harmonic generation, theory      86—89
Self-defocusing, thermal      330—331
Self-focusing      303—333
Self-focusing as result of stimulated Rayleigh scattering      199
Self-focusing in amplifying media      323
Self-focusing in gases      323
Self-focusing in liquids with colloidal suspension      323
Self-focusing in plasmas      548 553
Self-focusing in solids      321—322 530 537
Self-focusing vs. self-trapping      308 311—312
Self-focusing vs. stimulated Raman scattering      307 316—319
Self-focusing, CW      323
Self-focusing, physical description      303—307
Self-focusing, polarization dependence      314
Self-focusing, quasi-steady-state      313—319
Self-focusing, quasi-steady-state, connection with anomalous stimulated Raman and Brillouin effects      316—319
Self-focusing, quasi-steady-state, critical beam size      313—314
Self-focusing, quasi-steady-state, filament and moving focus      314—319
Self-focusing, quasi-steady-state, filament diameter      315 319
Self-focusing, quasi-steady-state, moving focal spot      315—316
Self-focusing, quasi-steady-state, transient dynamics in focal region      319
Self-focusing, quasi-steady-state, U-curve for      315—318
Self-focusing, resulting from optical-field-induced refractive index      303
Self-focusing, resulting in damage in solids      322
Self-focusing, resulting in filaments      314—315 320 323
Self-focusing, theory      307—313
Self-focusing, thermal      323
Self-focusing, transient      319—321
Self-focusing, transient as dynamic self-trapping      320
Self-focusing, transient from quasi-steady-state to transient      321
Self-focusing, transient, filament formation      320
Self-focusing, transient, formation of horn-shaped pulse      320
Self-focusing, transient, qualitative description      319—321
Self-induced transparency      401—407
Self-induced transparency, $2n\pi$ pulse      401 404—406
Self-induced transparency, basic idea      401—402
Self-induced transparency, characteristics of      406
Self-induced transparency, hyperbolic secant pulse      404
Self-induced transparency, pendulum equation for      403
Self-phase modulation      324—329

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