Microcavities:
Gespeichert in:
| Format: | Buch |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
Oxford [u.a.]
Oxford Univ. Press
2007
|
| Ausgabe: | 1. publ. |
| Schriftenreihe: | Series on semiconductor science and technology
16 |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XVII, 430 S. Ill., graph. Darst. |
| ISBN: | 0199228949 9780199228942 |
Internformat
MARC
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| 490 | 1 | |a Series on semiconductor science and technology |v 16 | |
| 650 | 4 | |a Electromagnetic interactions | |
| 650 | 4 | |a Lasers | |
| 650 | 4 | |a Quantum electrodynamics | |
| 650 | 4 | |a Semiconductors | |
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Datensatz im Suchindex
| _version_ | 1804137223485915136 |
|---|---|
| adam_text | CONTENTS
1 Overview of Microcavities 1
1.1 Properties of microcavities 2
1.1.1 Q-factor and finesse 2
1.1.2 Intracavity field enhancement and field distribution 3
1.1.3 Tuneability and mode separation 3
1.1.4 Angular mode pattern 4
1.1.5 Low-threshold lasing 4
1.1.6 Purcell factor and lifetimes 5
1.1.7 Strong vs. weak coupling 5
1.2 Microcavity realizations 5
1.3 Planar microcavities 6
1.3.1 Metal microcavities 8
1.3.2 Dielectric Bragg mirrors 9
1.4 Spherical mirror microcavities 10
1.5 Pillar microcavities 12
1.6 Whispering-gallery modes 15
1.6.1 Two-dimensional whispering galleries 16
1.6.2 Three-dimensional whispering-galleries 18
1.7 Photonic-crystal cavities 19
1.7.1 Random lasers 20
1.8 Plasmonic cavities 20
1.9 Microcavity lasers 21
1.10 Conclusion 21
2 Classical description of light 23
2.1 Free space 24
2.1.1 Light-field dynamics in free space 24
2.2 Propagation in crystals 27
2.2.1 Plane waves in bulk crystals 27
2.2.2 Absorption of light 31
2.2.3 Kramers-Kronig relations 32
2.3 Coherence 32
2.3.1 Statistical properties of light 32
2.3.2 Spatial and temporal coherence 33
2.3.3 Wiener-Khinchin theorem 38
2.3.4 Hanbury Brown-Twiss effect 41
2.4 Polarization-dependent optical effects 43
2.4.1 Birefringence 43
2.4.2 Magneto-optical effects 44
2.5 Propagation of light in multilayer planar structures 45
xiii
xiv CONTENTS
2.6 Photonic eigenmodes of planar systems 49
2.6.1 Photonic bands of ID periodic structures 52
2.7 Planar microcavities 59
2.8 Stripes, pillars, and spheres: photonic wires and dots 64
2.8.1 Cylinders and pillar cavities 66
2.8.2 Spheres 69
2.9 Further reading 73
3 Quantum description of light 75
3.1 Pictures of quantum mechanics 76
3.1.1 Historical background 76
3.1.2 Schrodinger picture 76
3.1.3 Antisymmetry of the wavefunction 85
3.1.4 Symmetry of the wavefunction 86
3.1.5 Heisenberg picture 88
3.1.6 Dirac (interaction) picture 93
3.2 Other formulations 95
3.2.1 Density matrix 95
3.2.2 Second quantization 97
3.2.3 Quantization of the light field 99
3.3 Quantum states 100
3.3.1 Fock states 100
3.3.2 Coherent states 101
3.3.3 Glauber-Sudarshan representation 102
3.3.4 Thermal states 103
3.3.5 Mixture states 105
3.3.6 Quantum correlations of quantum fields 106
3.3.7 Statistics of the field 110
3.3.8 Polarization 113
3.4 Outlook on quantum mechanics for microcavities 115
3.5 Further reading 116
4 Semiclassical description of light-matter coupling 117
4.1 Light-matter interaction 118
4.1.1 Classical limit 118
4.1.2 Einstein coefficients 120
4.2 Optical transitions in semiconductors 123
4.3 Excitons in semiconductors 127
4.3.1 Frenkel and Wannier-Mott excitons 127
4.3.2 Excitons in confined systems 131
4.3.3 Quantum wells 132
4.3.4 Quantum wires and dots 135
4.4 Exciton-photon coupling 137
4.4.1 Surface polaritons 140
4.4.2 Exciton-photon coupling in quantum wells 142
CONTENTS xv
4.4.3 Exciton-photon coupling in quantum wires and dots 147
4.4.4 Dispersion of polaritons in planar microcavities 150
4.4.5 Motional narrowing of cavity polaritons 160
4.4.6 Microcavities with quantum wires or dots 164
5 Quantum description of light-matter coupling in semiconductors 169
5.1 Historical background 170
5.2 Rabi dynamics 170
5.3 Bloch equations 173
5.3.1 Full quantum picture 176
5.3.2 Dressed bosons 179
5.4 Lindblad dissipation 187
5.5 Jaynes-Cummings model 192
5.6 Dicke model 198
5.7 Excitons in semiconductors 199
5.7.1 Quantization of the exciton field 200
5.7.2 Excitons as bosons 202
5.7.3 Excitons in quantum dots 202
5.8 Exciton-photon coupling 208
5.8.1 Dispersion of polaritons 210
5.8.2 The polariton Hamiltonian 211
5.8.3 Coupling in quantum dots 213
6 Weak-coupling microcavities 215
6.1 Purcell effect 216
6.1.1 The physics of weak coupling 216
6.1.2 Spontaneous emission 217
6.1.3 The case of QDs, 2D excitons and 2D electron-hole pairs 219
6.1.4 Fermi s golden rule 220
6.1.5 Dynamics of the Purcell effect 223
6.1.6 Case of QDs and QWs 225
6.1.7 Experimental realizations 226
6.2 Lasers 228
6.2.1 The physics of lasers 229
6.2.2 Semiconductors in laser physics 233
6.2.3 Vertical-cavity surface-emitting lasers 236
6.2.4 Resonant-cavity LEDs 240
6.2.5 Quantum theory of the laser 241
6.3 Nonlinear optical properties of weak-coupling microcavities 246
6.3.1 Bistability 247
6.3.2 Phase matching 249
6.4 Conclusion 249
7 Strong coupling: resonant effects 251
7.1 Optical properties background 252
xvi CONTENTS
7.1.1 Quantum well microcavities 252
7.1.2 Variations on a theme 254
7.1.3 Motional narrowing 256
7.1.4 Polariton emission 256
7.2 Near-resonant-pumped optical nonlinearities 258
7.2.1 Pulsed stimulated scattering 258
7.2.2 Quasimode theory of parametric amplification 263
7.2.3 Microcavity parametric oscillators 265
7.3 Resonant excitation case and parametric amplification 268
7.3.1 Semiclassical description 268
7.3.2 Stationary solution and threshold 269
7.3.3 Theoretical approach: quantum model 270
7.3.4 Three-level model 271
7.3.5 Threshold 274
7.4 Two-beam experiment 274
7.4.1 One-beam experiment and spontaneous symmetry breaking 274
7.4.2 Dressing of the dispersion induced by polariton condensates 276
7.4.3 Bistable behaviour 277
8 Strong coupling: polariton Bose condensation 279
8.1 Introduction 280
8.2 Basic ideas about Bose-Einstein condensation 280
8.2.1 Einstein proposal 280
8.2.2 Experimental realization 282
8.2.3 Modern definition of Bose-Einstein condensation 283
8.3 Specificities of excitons and polaritons 284
8.3.1 Thermodynamic properties of cavity polaritons 285
8.3.2 Interacting bosons and Bogoliubov model 286
8.3.3 Polariton superfluidity 289
8.3.4 Quasicondensation and local effects 292
8.4 High-power microcavity emission 294
8.5 Thresholdless polariton lasing 297
8.6 Kinetics of formation of polariton condensates: semiclassical picture 302
8.6.1 Qualitative features 302
8.6.2 The semiclassical Boltzmann equation 305
8.6.3 Numerical solution of Boltzmann equations, practical aspects 307
8.6.4 Effective scattering rates 307
8.6.5 Numerical simulations 308
8.7 Kinetics of formation of polariton condensates: quantum picture in the
Born-Markov approximation 310
8.7.1 Density matrix dynamics of the ground-state 312
8.7.2 Discussion 316
8.7.3 Coherence dynamics 317
CONTENTS xvii
8.8 Kinetics of formation of polariton condensates: quantum picture beyond
the Born-Markov approximation 319
8.8.1 Two-oscillator toy theory 319
8.8.2 Coherence of polariton-laser emission 329
8.8.3 Numerical simulations 335
8.8.4 Order parameter and phase diffusion coefficient 336
8.9 Semiconductor luminescence equations 338
8.10 Claims of exciton and polariton Bose-Einstein condensation 341
8.11 Further reading 342
9 Spin and polarization 345
9.1 Spin relaxation of electrons, holes and excitons in semiconductors 346
9.2 Microcavities in the presence of a magnetic field 351
9.3 Resonant Faraday rotation 352
9.4 Spin relaxation of exciton-polaritons in microcavities: experiment 355
9.5 Spin relaxation of exciton-polaritons in microcavities: theory 360
9.6 Optical spin Hall effect 364
9.7 Optically induced Faraday rotation 366
9.8 Interplay between spin and energy relaxation of exciton-polaritons 368
9.9 Polarization of Bose condensates and polariton superfluidity 372
9.10 Magnetic-field effect and superfluidity 374
9.11 Finite-temperature case 378
9.12 Spin dynamics in parametric oscillators 381
9.13 Classical nonlinear optics consideration 381
9.14 Polarized OPO: quantum model 383
9.15 Conclusions 385
9.16 Further reading 386
Glossary 387
A Linear algebra 395
B Scattering rates of polariton relaxation 399
B.I Polariton-phonon interaction 399
B. 1.1 Interaction with longitudinal optical phonons 400
B. 1.2 Interaction with acoustic phonons 401
B.2 Polariton-electron interaction 402
B.3 Polariton-polariton interaction 404
B.3.1 Polariton decay 404
B.4 Polariton-structural-disorder interaction 405
C Derivation of the Landau criterion of superfluidity and Landau formula 407
D Landau quantization and renormalization of Rabi splitting 409
References 413
|
| adam_txt |
CONTENTS
1 Overview of Microcavities 1
1.1 Properties of microcavities 2
1.1.1 Q-factor and finesse 2
1.1.2 Intracavity field enhancement and field distribution 3
1.1.3 Tuneability and mode separation 3
1.1.4 Angular mode pattern 4
1.1.5 Low-threshold lasing 4
1.1.6 Purcell factor and lifetimes 5
1.1.7 Strong vs. weak coupling 5
1.2 Microcavity realizations 5
1.3 Planar microcavities 6
1.3.1 Metal microcavities 8
1.3.2 Dielectric Bragg mirrors 9
1.4 Spherical mirror microcavities 10
1.5 Pillar microcavities 12
1.6 Whispering-gallery modes 15
1.6.1 Two-dimensional whispering galleries 16
1.6.2 Three-dimensional whispering-galleries 18
1.7 Photonic-crystal cavities 19
1.7.1 Random lasers 20
1.8 Plasmonic cavities 20
1.9 Microcavity lasers 21
1.10 Conclusion 21
2 Classical description of light 23
2.1 Free space 24
2.1.1 Light-field dynamics in free space 24
2.2 Propagation in crystals 27
2.2.1 Plane waves in bulk crystals 27
2.2.2 Absorption of light 31
2.2.3 Kramers-Kronig relations 32
2.3 Coherence 32
2.3.1 Statistical properties of light 32
2.3.2 Spatial and temporal coherence 33
2.3.3 Wiener-Khinchin theorem 38
2.3.4 Hanbury Brown-Twiss effect 41
2.4 Polarization-dependent optical effects 43
2.4.1 Birefringence 43
2.4.2 Magneto-optical effects 44
2.5 Propagation of light in multilayer planar structures 45
xiii
xiv CONTENTS
2.6 Photonic eigenmodes of planar systems 49
2.6.1 Photonic bands of ID periodic structures 52
2.7 Planar microcavities 59
2.8 Stripes, pillars, and spheres: photonic wires and dots 64
2.8.1 Cylinders and pillar cavities 66
2.8.2 Spheres 69
2.9 Further reading 73
3 Quantum description of light 75
3.1 Pictures of quantum mechanics 76
3.1.1 Historical background 76
3.1.2 Schrodinger picture 76
3.1.3 Antisymmetry of the wavefunction 85
3.1.4 Symmetry of the wavefunction 86
3.1.5 Heisenberg picture 88
3.1.6 Dirac (interaction) picture 93
3.2 Other formulations 95
3.2.1 Density matrix 95
3.2.2 Second quantization 97
3.2.3 Quantization of the light field 99
3.3 Quantum states 100
3.3.1 Fock states 100
3.3.2 Coherent states 101
3.3.3 Glauber-Sudarshan representation 102
3.3.4 Thermal states 103
3.3.5 Mixture states 105
3.3.6 Quantum correlations of quantum fields 106
3.3.7 Statistics of the field 110
3.3.8 Polarization 113
3.4 Outlook on quantum mechanics for microcavities 115
3.5 Further reading 116
4 Semiclassical description of light-matter coupling 117
4.1 Light-matter interaction 118
4.1.1 Classical limit 118
4.1.2 Einstein coefficients 120
4.2 Optical transitions in semiconductors 123
4.3 Excitons in semiconductors 127
4.3.1 Frenkel and Wannier-Mott excitons 127
4.3.2 Excitons in confined systems 131
4.3.3 Quantum wells 132
4.3.4 Quantum wires and dots 135
4.4 Exciton-photon coupling 137
4.4.1 Surface polaritons 140
4.4.2 Exciton-photon coupling in quantum wells 142
CONTENTS xv
4.4.3 Exciton-photon coupling in quantum wires and dots 147
4.4.4 Dispersion of polaritons in planar microcavities 150
4.4.5 Motional narrowing of cavity polaritons 160
4.4.6 Microcavities with quantum wires or dots 164
5 Quantum description of light-matter coupling in semiconductors 169
5.1 Historical background 170
5.2 Rabi dynamics 170
5.3 Bloch equations 173
5.3.1 Full quantum picture 176
5.3.2 Dressed bosons 179
5.4 Lindblad dissipation 187
5.5 Jaynes-Cummings model 192
5.6 Dicke model 198
5.7 Excitons in semiconductors 199
5.7.1 Quantization of the exciton field 200
5.7.2 Excitons as bosons 202
5.7.3 Excitons in quantum dots 202
5.8 Exciton-photon coupling 208
5.8.1 Dispersion of polaritons 210
5.8.2 The polariton Hamiltonian 211
5.8.3 Coupling in quantum dots 213
6 Weak-coupling microcavities 215
6.1 Purcell effect 216
6.1.1 The physics of weak coupling 216
6.1.2 Spontaneous emission 217
6.1.3 The case of QDs, 2D excitons and 2D electron-hole pairs 219
6.1.4 Fermi's golden rule 220
6.1.5 Dynamics of the Purcell effect 223
6.1.6 Case of QDs and QWs 225
6.1.7 Experimental realizations 226
6.2 Lasers 228
6.2.1 The physics of lasers 229
6.2.2 Semiconductors in laser physics 233
6.2.3 Vertical-cavity surface-emitting lasers 236
6.2.4 Resonant-cavity LEDs 240
6.2.5 Quantum theory of the laser 241
6.3 Nonlinear optical properties of weak-coupling microcavities 246
6.3.1 Bistability 247
6.3.2 Phase matching 249
6.4 Conclusion 249
7 Strong coupling: resonant effects 251
7.1 Optical properties background 252
xvi CONTENTS
7.1.1 Quantum well microcavities 252
7.1.2 Variations on a theme 254
7.1.3 Motional narrowing 256
7.1.4 Polariton emission 256
7.2 Near-resonant-pumped optical nonlinearities 258
7.2.1 Pulsed stimulated scattering 258
7.2.2 Quasimode theory of parametric amplification 263
7.2.3 Microcavity parametric oscillators 265
7.3 Resonant excitation case and parametric amplification 268
7.3.1 Semiclassical description 268
7.3.2 Stationary solution and threshold 269
7.3.3 Theoretical approach: quantum model 270
7.3.4 Three-level model 271
7.3.5 Threshold 274
7.4 Two-beam experiment 274
7.4.1 One-beam experiment and spontaneous symmetry breaking 274
7.4.2 Dressing of the dispersion induced by polariton condensates 276
7.4.3 Bistable behaviour 277
8 Strong coupling: polariton Bose condensation 279
8.1 Introduction 280
8.2 Basic ideas about Bose-Einstein condensation 280
8.2.1 Einstein proposal 280
8.2.2 Experimental realization 282
8.2.3 Modern definition of Bose-Einstein condensation 283
8.3 Specificities of excitons and polaritons 284
8.3.1 Thermodynamic properties of cavity polaritons 285
8.3.2 Interacting bosons and Bogoliubov model 286
8.3.3 Polariton superfluidity 289
8.3.4 Quasicondensation and local effects 292
8.4 High-power microcavity emission 294
8.5 Thresholdless polariton lasing 297
8.6 Kinetics of formation of polariton condensates: semiclassical picture 302
8.6.1 Qualitative features 302
8.6.2 The semiclassical Boltzmann equation 305
8.6.3 Numerical solution of Boltzmann equations, practical aspects 307
8.6.4 Effective scattering rates 307
8.6.5 Numerical simulations 308
8.7 Kinetics of formation of polariton condensates: quantum picture in the
Born-Markov approximation 310
8.7.1 Density matrix dynamics of the ground-state 312
8.7.2 Discussion 316
8.7.3 Coherence dynamics 317
CONTENTS xvii
8.8 Kinetics of formation of polariton condensates: quantum picture beyond
the Born-Markov approximation 319
8.8.1 Two-oscillator toy theory 319
8.8.2 Coherence of polariton-laser emission 329
8.8.3 Numerical simulations 335
8.8.4 Order parameter and phase diffusion coefficient 336
8.9 Semiconductor luminescence equations 338
8.10 Claims of exciton and polariton Bose-Einstein condensation 341
8.11 Further reading 342
9 Spin and polarization 345
9.1 Spin relaxation of electrons, holes and excitons in semiconductors 346
9.2 Microcavities in the presence of a magnetic field 351
9.3 Resonant Faraday rotation 352
9.4 Spin relaxation of exciton-polaritons in microcavities: experiment 355
9.5 Spin relaxation of exciton-polaritons in microcavities: theory 360
9.6 Optical spin Hall effect 364
9.7 Optically induced Faraday rotation 366
9.8 Interplay between spin and energy relaxation of exciton-polaritons 368
9.9 Polarization of Bose condensates and polariton superfluidity 372
9.10 Magnetic-field effect and superfluidity 374
9.11 Finite-temperature case 378
9.12 Spin dynamics in parametric oscillators 381
9.13 Classical nonlinear optics consideration 381
9.14 Polarized OPO: quantum model 383
9.15 Conclusions 385
9.16 Further reading 386
Glossary 387
A Linear algebra 395
B Scattering rates of polariton relaxation 399
B.I Polariton-phonon interaction 399
B. 1.1 Interaction with longitudinal optical phonons 400
B. 1.2 Interaction with acoustic phonons 401
B.2 Polariton-electron interaction 402
B.3 Polariton-polariton interaction 404
B.3.1 Polariton decay 404
B.4 Polariton-structural-disorder interaction 405
C Derivation of the Landau criterion of superfluidity and Landau formula 407
D Landau quantization and renormalization of Rabi splitting 409
References 413 |
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| callnumber-sort | TA 41677 |
| callnumber-subject | TA - General and Civil Engineering |
| classification_rvk | UH 5680 |
| ctrlnum | (OCoLC)153553936 (DE-599)BVBBV023009668 |
| dewey-full | 621.36 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 621 - Applied physics |
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| discipline | Physik Elektrotechnik / Elektronik / Nachrichtentechnik |
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| id | DE-604.BV023009668 |
| illustrated | Illustrated |
| index_date | 2024-07-02T19:08:55Z |
| indexdate | 2024-07-09T21:08:53Z |
| institution | BVB |
| isbn | 0199228949 9780199228942 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-016213901 |
| oclc_num | 153553936 |
| open_access_boolean | |
| owner | DE-703 DE-20 DE-83 DE-11 |
| owner_facet | DE-703 DE-20 DE-83 DE-11 |
| physical | XVII, 430 S. Ill., graph. Darst. |
| publishDate | 2007 |
| publishDateSearch | 2007 |
| publishDateSort | 2007 |
| publisher | Oxford Univ. Press |
| record_format | marc |
| series | Series on semiconductor science and technology |
| series2 | Series on semiconductor science and technology |
| spelling | Microcavities Alexey V. Kavokin ... 1. publ. Oxford [u.a.] Oxford Univ. Press 2007 XVII, 430 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Series on semiconductor science and technology 16 Electromagnetic interactions Lasers Quantum electrodynamics Semiconductors Mikrowellenresonator (DE-588)4169890-3 gnd rswk-swf Exziton-Polariton (DE-588)4153442-6 gnd rswk-swf Photonik (DE-588)4243979-6 gnd rswk-swf Mikrostruktur (DE-588)4131028-7 gnd rswk-swf Quantenoptik (DE-588)4047990-0 gnd rswk-swf Optischer Resonator (DE-588)4172678-9 gnd rswk-swf Mikrooptik (DE-588)4362762-6 gnd rswk-swf Mikrowellenresonator (DE-588)4169890-3 s Photonik (DE-588)4243979-6 s DE-604 Optischer Resonator (DE-588)4172678-9 s Mikrostruktur (DE-588)4131028-7 s Quantenoptik (DE-588)4047990-0 s 1\p DE-604 Mikrooptik (DE-588)4362762-6 s 2\p DE-604 Exziton-Polariton (DE-588)4153442-6 s 3\p DE-604 Kavokin, Alexey Sonstige oth Series on semiconductor science and technology 16 (DE-604)BV004175002 16 HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016213901&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk 2\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk 3\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk |
| spellingShingle | Microcavities Series on semiconductor science and technology Electromagnetic interactions Lasers Quantum electrodynamics Semiconductors Mikrowellenresonator (DE-588)4169890-3 gnd Exziton-Polariton (DE-588)4153442-6 gnd Photonik (DE-588)4243979-6 gnd Mikrostruktur (DE-588)4131028-7 gnd Quantenoptik (DE-588)4047990-0 gnd Optischer Resonator (DE-588)4172678-9 gnd Mikrooptik (DE-588)4362762-6 gnd |
| subject_GND | (DE-588)4169890-3 (DE-588)4153442-6 (DE-588)4243979-6 (DE-588)4131028-7 (DE-588)4047990-0 (DE-588)4172678-9 (DE-588)4362762-6 |
| title | Microcavities |
| title_auth | Microcavities |
| title_exact_search | Microcavities |
| title_exact_search_txtP | Microcavities |
| title_full | Microcavities Alexey V. Kavokin ... |
| title_fullStr | Microcavities Alexey V. Kavokin ... |
| title_full_unstemmed | Microcavities Alexey V. Kavokin ... |
| title_short | Microcavities |
| title_sort | microcavities |
| topic | Electromagnetic interactions Lasers Quantum electrodynamics Semiconductors Mikrowellenresonator (DE-588)4169890-3 gnd Exziton-Polariton (DE-588)4153442-6 gnd Photonik (DE-588)4243979-6 gnd Mikrostruktur (DE-588)4131028-7 gnd Quantenoptik (DE-588)4047990-0 gnd Optischer Resonator (DE-588)4172678-9 gnd Mikrooptik (DE-588)4362762-6 gnd |
| topic_facet | Electromagnetic interactions Lasers Quantum electrodynamics Semiconductors Mikrowellenresonator Exziton-Polariton Photonik Mikrostruktur Quantenoptik Optischer Resonator Mikrooptik |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016213901&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| volume_link | (DE-604)BV004175002 |
| work_keys_str_mv | AT kavokinalexey microcavities |