Optics, Light and Lasers

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Dieter Meschede Optics, Light and Lasers The Practical Approach to Modern Aspects of Photonics and Laser Physics Second, Revised and Enlarged Edition BICENTENNIAL.... n 4 '':- t' 1 8 0 7 $W1LEY 2007 tri ni, 4 r BICENTENNIAL WILEY-VCH Verlag GmbH & Co. KGaA

v I Contents Preface IX 1 Light rays 1 1.1 Light rays in human experience / 1.2 Ray optics 2 1.3 Reflection 2 1.4 Refraction 3 1.5 Fermat's principle: the optical path length 5 1.6 Prisms 8 1.7 Light rays in wave guides 12 1.8 Lenses and curved mirrors 16 1.9 Matrix optics 19 1.10 Ray optics and particle optics 27 Problems for chapter 1 30 2 Wave optics 33 2.1 Electromagnetic radiation fields 33 2.2 Wave types 42 2.3 Gaussian beams 45 2.4 Polariation 56 2.5 Diffraction 60 Problems for chapter 2 77 3 Light propagation in matter 81 3.1 Dielectric interfaces 81 3.2 Complex refractive index 87 3.3 Optical wave guides and fibres 91 3.4 Functional types and applications of optical fibres 101 3.5 Photonic materials 104 3.6 Light pulses in dispersive materials 116 Optics, Light and Lasers: The Practical Approach to Modern Aspects of Photonics and Laser Physics, Second Edition. Dieter Meschede Copyright 2007 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

VI I Contents 3.7 Anisotropic optical materials 127 3.8 Optical modulators 135 Problems for chapter 3 146 4 Optical images 149 4.1 The human eye 150 4.2 Magnifying glass and eyepiece 151 4.3 Microscopes 153 4.4 Telescopes 160 4.5 Lenses: designs and aberrations 165 Problems for chapter 4 174 5 Coherence and interferometry 177 5.1 Young's double slit 177 5.2 Coherence and correlation 178 5.3 The double-slit experiment 181 5.4 Michelson interferometer: longitudinal coherence 189 5.5 Fabry Perot interferometer 195 5.6 Optical cavities 201 5.7 Thin optical films 207 5.8 Holography 211 5.9 Laser speckle (laser granulation) 215 Problems for chapter 5 218 6 Light and matter 221 6.1 Classical radiation interaction 222 6.2 Two-level atoms 232 6.3 Stimulated and spontaneous radiation processes 244 6.4 Inversion and amplification 248 Problems for chapter 6 253 7 The laser 255 7.1 The classic system: the He Ne laser 258 7.2 Mode selection in the He Ne laser 260 7.3 Spectral properties of the He Ne laser 266 7.4 Applications of the He Ne laser 269 7.5 Other gas lasers 269 7.6 Molecular gas lasers 272 7.7 The workhorses: solid-state lasers 277 7.8 Selected solid-state lasers 281 7.9 Tunable lasers with vibronic states 289 7.10 Tunable ring lasers 293 Problems for chapter 7 295

Contents IVII 8 Laser dynamics 297 8.1 Basic laser theory 297 8.2 Laser rate equations 304 8.3 Threshold-less lasers and micro-lasers 308 8.4 Laser noise 312 8.5 Pulsed lasers 320 Problems for chapter 8 332 9 Semiconductor lasers 333 9.1 Semiconductors 333 9.2 Optical properties of semiconductors 336 9.3 The heterostructure laser 346 9.4 Dynamic properties of semiconductor lasers 355 9.5 Laser diodes, diode lasers, laser systems 362 9.6 High-power laser diodes 366 Problems for chapter 9 369 10 Sensors for light 371 10.1 Characteristics of optical detectors 372 10.2 Fluctuating opto-electronic quantities 376 10.3 Photon noise and detectivity limits 378 10.4 Thermal detectors 384 10.5 Quantum sensors I: photomultiplier tubes 387 10.6 Quantum sensors II: semiconductor sensors 391 10.7 Position and image sensors 396 Problems for chapter 10 400 11 Laser spectroscopy 401 11.1 Laser-induced fluorescence (LIF) 401 11.2 Absorption and dispersion 402 11.3 The width of spectral lines 404 11.4 Doppler-free spectroscopy 411 11.5 Transient phenomena 418 11.6 Light forces 424 Problems for chapter 11 436 12 Photons an introduction to quantum optics 439 12.1 Does light exhibit quantum character? 439 12.2 Quantiation of the electromagnetic field 441 12.3 Spontaneous emission 444 12.4 Weak coupling and strong coupling 450 12.5 Resonance fluorescence 454

VIIil Contents 12.6 Light fields in quantum optics 463 12.7 Two-photon optics 474 12.8 Entangled photons 478 Problems for chapter 12 487 13 Nonlinear optics I: optical mixing processes 489 13.1 Charged anharmonic oscillators 489 13.2 Second-order nonlinear susceptibility 491 13.3 Wave propagation in nonlinear media 497 13.4 Frequency doubling 500 13.5 Sum and difference frequency 513 13.6 Optical parametric oscillators 515 Problems for chapter 13 519 14 Nonlinear optics II: four-wave mixing 521 14.1 Frequency tripling in gases 522 14.2 Nonlinear refraction coefficient (optical Kerr effect) 523 14.3 Self-phase modulation 531 Problems for chapter 14 532 Appendix A Mathematics for optics 533 A.1 Spectral analysis of fluctuating measurable quantities 533 A.2 Poynting theorem 539 B Supplements in quantum mechanics 541 B.1 Temporal evolution of a two-state system 541 B.2 Density-matrix formalism 542 B.3 Density of states 543 Bibliography 545 Index 553

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