 | | Kazantsev A.P., Surdutovich G.I., Yakovlev V.P. Mechanical action of light on atoms (Singapore; London: World Scientific, 1990. - 380 p.) |
| | | Оглавление |
|
Preface ........................................................... v
Introduction ...................................................... 1
Chapter 1. Coherent Interaction between Atoms and Field ........... 9
1. The Hamiltonian of Atom-Field Interaction .................. 9
2. Light Pressure Force ...................................... 18
2.1. Adiabatic states. Nonresonant potential ............. 24
2.2. Diabatic states. Resonant potential ................. 28
2.3. Atomic density-matrix equation with allowance
for a recoil effect ................................. 31
3. The Non-Adiabaticity Operator. Landau-Zener (LZ)
Transitions ............................................... 33
Chapter 2. Scattering of Atoms by Light .......................... 45
4. The Classical Picture of Scattering ....................... 45
5. Acceleration of Atoms by Light ............................ 58
6. Diffraction of Atoms ...................................... 68
6.1. Diffraction of a "coherent" atomic beam ............. 68
6.2. Experiment .......................................... 71
6.3. Bragg scattering .................................... 73
6.4. The scattering of atoms by a quantized
electromagnetic field ............................... 76
7. The Interference of Atoms ................................. 81
7.1. The interference of atoms scattered by a single
standing wave ....................................... 82
7.2. The transfer of the spatial coherence under the
Echo conditions ..................................... 85
7.3. Pulse scattering regime ............................. 87
7.4. Nonlinear atomic interferometry ..................... 88
7.5. The Bohm-Aaronov effect ............................. 89
7.6. The interference of atoms in a gas .................. 89
7.7. Combined scattering regime .......................... 91
Chapter 3. Dispersion of Atoms in Light Fields ................... 95
8. Dispersion of Atoms in the Periodic Light Field ........... 95
8.1. Travelling wave ..................................... 96
8.2. Atoms in a standing wave. Symmetry of the
problem ............................................. 98
8.3. Dispersion law for a weak field .................... 100
9. A Strong Field Case. The Above-Barrier Motion ............ 103
9.1. The scalar particle in a periodic potential ........ 104
9.2. The influence of the Landau-Zener transitions ...... 105
9.3. The Bloch functions of an atom in a
standing-wave field ................................ 108
9.4. Optical characteristics of atoms in a
standing-wave field ................................ 109
10. The Under-Barrier Motion of Atoms in a
Strong Field ............................................. 113
10.1. The bipotential motion (Δ/2 < ε < V0).
Strong coupling approximation (small Δ) ............ 113
10.2. The lifetime of bound states of atoms
at large Δ ......................................... 117
10.3. The quasiclassical analysis of the sub-
barrier motion ..................................... 122
11. Bipotential Scattering ................................... 130
Chapter 4. Influence of Spontaneous Radiation on Light
Pressure Force ....................................... 141
12. Equation for the Atomic Density Matrix ................... 142
13. The Light Pressure Force and the Hysteresis
Phenomenon ............................................... 150
13.1. Light pressure force in the travelling wave ........ 152
13.2. Light pressure force in the standing wave .......... 153
13.3. Peculiarities of the perturbation theory in
the field of a standing wave ....................... 155
13.4. Strong field. Quasistationary approximation ........ 161
13.5. Strong field. Quasiclassical approximation.
LZ-transitions ..................................... 168
13.6. Friction force for fast atoms ...................... 176
14. Light Pressure Force and Spectrum of Resonance
Fluorescence ............................................. 178
14.1. Atomic correlation matrix with allowance
for recoil ......................................... 178
14.2. Spectrum resonance fluorescence in the field
of a travelling wave ............................... 183
14.3. Relationship between the light pressure force
and spectrum of resonance fluorescence ............. 186
14.4. Spectrum of resonance fluorescence in the
field of a standing wave ........................... 189
15. Cooling and Velocity Bunching of Atoms in the
Light Field .............................................. 194
15.1. Deceleration of atoms in the intense
standing wave ...................................... 194
15.2. Cooling of atoms by the spontaneous light
pressure force ..................................... 196
15.3. Coooling of trapped ions by the light field ........ 196
15.4. Bunching of atoms in the velocity space ............ 201
16. Interference Phenomena and the Effect of
Rectification of the Radiation Force ..................... 212
16.1. Interference phenomena in the monochromatic
field .............................................. 212
16.2. Interference phenomena in a weak bichromatic
field .............................................. 217
16.3. Bichromatic fields of finite amplitude ............. 219
Chapter 5. Kinetics of Atoms in Light Fields .................... 227
17. Kinetics of Atoms in the Travelling Wave Field ........... 228
17.1. The Fokker-Planck kinetic equation ................. 228
17.2. Slow bunching in velocities of atoms in
the travelling wave field .......................... 231
17.3. Rapid velocity bunching in the presence
of magnetic field .................................. 235
17.4. Influence of the light pressure on the
nonlinear susceptibility of resonance atoms ........ 236
18. Kinetics of Atoms in a Weak Standing-Wave Field .......... 241
18.1. Kinetic equation in linear approximation in
the field strength ................................. 241
18.2. Evolution of the velocity distribution in
a weak standing-wave field ......................... 247
18.3. Viscous confinement in a field of the three
orthogonal standing waves .......................... 253
18.4. Nonlinear susceptibility of resonance atoms
in a standing-wave field ........................... 254
19. Kinetic Equation for Slow Atoms in a Standing-Wave
Field .................................................... 256
19.1. Derivation of the kinetic equation ................. 257
19.2. Properties of the kinetic coefficients ............. 260
19.3. Light pressure force in a laser beam of
finite radius ...................................... 264
20. Scattering of Atoms by a Standing Wave in the
Kinetic Regime ........................................... 267
21. Cooling and Localization of Atoms in a Strong
Standing Light Wave ...................................... 276
21.1. Stationary solution of the kinetic equation ........ 277
21.2. Effective temperature of the untrapped
particles .......................................... 279
21.3. One-dimensional lattice of cooled atoms and
the channelling phenomenon ......................... 281
21.4. Three-dimensional lattice of cooled atom ........... 285
21.5. Lifetime of atoms in the light-wave grating ........ 288
21.6. Viscous confinement in a saturating field .......... 289
22. Localization of Atoms in Strong Fields ................... 291
22.1. Motion of atoms in the focus of a laser beam ....... 292
22.2. Localization of atoms by light and
magnetic fields .................................... 295
22.3. Localization of atoms in a bichromatic field ....... 297
23. Kinetics of Fast Atoms in a Standing Light Wave .......... 299
23.1. Kinetics of atoms under strong hysteresis .......... 300
23.2. Fokker-Planck equation for fast atoms .............. 302
23.3. Strong field. Bipotential kinetics ................. 306
24. Diffraction, Diffusion and Potential Scattering
Atoms in a Standing-Light Wave Field ..................... 308
24.1. Basic equations .................................... 309
24.2. The case of large detunings. Spatial correlation
of spontaneous and induced transitions ............. 311
24.3. Diffraction scattering ............................. 315
24.4. Incoherent scattering .............................. 317
24.5. Statistics of scattered photons .................... 320
25. Polarization Effects in the Resonance Light
Pressure ................................................. 320
25.1. Equation for the density matrix .................... 321
25.2. Magnetization of atoms by the linearly
polarized wave ..................................... 326
26. Density Effects .......................................... 330
26.1. Atomic collisions in a light field ................. 330
26.2. The interaction of atoms in a light field .......... 333
Appendix I. Diffraction of Atoms from a Standing-Wave
Field with Smooth Temporal Envelope ............... 337
Appendix II. Effects of Spontaneous Relaxation in the Transfer
of Spatial Coherence under the Echo Conditions .... 341
Appendix III. General Form of the Dispersion Law for
Atoms in a Standing-Wave Field .................... 347
Appendix IV. Dispersion of an Atom in a Strong Standing Wave
under Small Detunings from Resonance .............. 353
Appendix V. Solution of the Bloch Equations Near the
Standing-Wave Nodes ............................... 363
References ...................................................... 367
Subject Index ................................................... 375
|
| Kazantsev A.P. Mechanical action of light on atoms / Kazantsev A.P., Surdutovich G.I., Yakovlev V.P. - Singapore; London: World Scientific, 1990. - 380 p. - Bibliogr.: 151 ref. |
|
