BIBLIOGRAPHY[168] Sto<strong>of</strong>,H.T.C.Coherent versus incoherent dynamics during <strong>Bose</strong>-<strong>Einstein</strong> condensationin atomic gases. Journal <strong>of</strong> Low Temperature <strong>Physics</strong> 114, 1–2 (1999),11–108.[169] Sudarshan, E. C. G. Equivalence <strong>of</strong> semiclassical and quantum mechanical descriptions<strong>of</strong> statistical light beams. Physical Review Letters 10, 7 (Apr. 1 1963),277–279.[170] Tempere, J., and Devreese, J. T. Fringe pattern <strong>of</strong> interfering <strong>Bose</strong>-<strong>Einstein</strong>condensates with a vortex. Solid State Communications 108, 12 (1998), 993–997.[171] Uzunov, I. M., and Gerdjikov, V. S. Self-frequency shift <strong>of</strong> dark solitons inoptical fibers. Physical Review A 47, 2 (Feb. 1993), 1582–1585.[172] von Foerster, T., and Glauber, R. J. <strong>Quantum</strong> theory <strong>of</strong> light propagationin amplifying media. Physical Review A 3, 4 (Apr. 1971), 1484–1511.[173] Wallis, H., Röhrl, A., Naraschewski, M., and Schenzle, A. Phase-spacedynamics <strong>of</strong> <strong>Bose</strong> condensates: Interference versus interaction. Physical Review A55, 3 (Mar. 1997), 2109–2119.[174] Walls, D. F., and Milburn, G. J. <strong>Quantum</strong> Optics. Springer-Verlag, Berlin,1994.[175] Walser, R., Williams, J., Cooper, J., and Holland, M. <strong>Quantum</strong> kinetictheory for a condensed bosonic gas. Physical Review A 59, 5 (May 1999), 3878–3889.[176] Werner, M. J., and Drummond, P. D. Robust algorithms for solving stochasticpartial differential equations. Journal <strong>of</strong> Computational <strong>Physics</strong> 132, 2 (Apr. 1997),312–326.[177] Wineland, D. J., Bollinger, J. J., Itano, W. M., and Heinzen, D. J.Squeezed atomic states and projection noise in spectroscopy. Physical Review A 50,1 (July 1994), 67–87.[178] Wineland, D. J., Bollinger, J. J., Itano, W. M., Moore, F. L., andHeinzen, D. J. Spin squeezing and reduced quantum noise in spectroscopy. PhysicalReview A 46, 11 (Dec. 1992), R6797–R6800.191
BIBLIOGRAPHY[179] Wiseman, H. M. <strong>Quantum</strong> trajectories and feedback. PhD thesis, The University<strong>of</strong> Queensland, 1994.[180] Wiseman, H. M. SU(2) distribution functions and measurement <strong>of</strong> the fluorescence<strong>of</strong> a two-level atom. Jornal <strong>of</strong> <strong>Quantum</strong> and Semiclassical Optics 7 (1995), 569–584.[181] Wiseman, H. M., and Milburn, G. J. <strong>Quantum</strong> theory <strong>of</strong> field-quadraturemeasurements. Physical Review A 47, 1 (Jan. 1993), 642–662.[182] Wood, D. Constraints on the bit rates in direct detection optical communicationsystems using linear or soliton pulses. Journal <strong>of</strong> Lightwave Technology 8, 7(July1990), 1097–1106.[183] Wu, H., Armondo, E., and Foot, C. J. <strong>Dynamics</strong> <strong>of</strong> evaporative cooling for<strong>Bose</strong>-<strong>Einstein</strong> condensation. Physical Review A 56, 1 (July 1997), 560–569.[184] Yamashita, M., Koashi, M., and Imoto, N. <strong>Quantum</strong> kinetic theory for evaporativecooling <strong>of</strong> trapped atoms: Growth <strong>of</strong> <strong>Bose</strong>-<strong>Einstein</strong> condensate.Review A 59, 3 (Mar. 1999), 2243–2249.Physical[185] Yoon, B., and Negele, J. W. Time-dependent Hartree approximation for aone-dimensional system <strong>of</strong> bosons with attractive δ-function interactions. PhysicalReview A 16, 4 (Oct. 1977), 1451–1457.[186] Young, B., Kasevich, M., and Chu, S. Precision atom interferometry withlight pulses. In Atom interferometry (1997), P. R. Bernan, Ed., Academic Press,pp. 363–405.[187] Yu, S.-S., and Lai, Y. Impacts <strong>of</strong> self-Raman effect and third-order dispersion onpulse squeezed state generation using optical fibres. Journal<strong>of</strong>theOpticalSociety<strong>of</strong> America B 12, 12 (Dec. 01 1995), 2340.[188] Yurke, B., and Potasek, M. J. Solution to the initial value problem for thequantum nonlinear Schrödinger equation. Journal<strong>of</strong>theOpticalSociety<strong>of</strong>AmericaB6, 6 (June 1989), 1227–1238.[189] Ziegler, K., and Shukla, A. <strong>Bose</strong>-<strong>Einstein</strong> condensation in a trap: The case <strong>of</strong>a dense condensate. Physical Review A 56, 2 (Aug. 1997), 1438–1442.192
- Page 1 and 2:
Open Quantum Dynamics of Mesoscopic
- Page 3 and 4:
AcknowledgementsMy thanks must firs
- Page 5 and 6:
AbstractThe properties of an atomic
- Page 7 and 8:
CONTENTS4 Continuously monitored Bo
- Page 9 and 10:
List of Figures2.1 Two-mode approxi
- Page 11 and 12:
LIST OF FIGURES7.5 Angular momentum
- Page 14 and 15:
LIST OF ABBREVIATIONS AND SYMBOLSI{
- Page 17 and 18:
1. Condensation ‘without forces
- Page 19 and 20:
1. Condensation ‘without forces
- Page 21 and 22:
Chapter 2Properties of an atomic Bo
- Page 23 and 24:
2. Properties of an atomic Bose con
- Page 25 and 26:
2. Properties of an atomic Bose con
- Page 27 and 28:
2. Properties of an atomic Bose con
- Page 29 and 30:
2. Properties of an atomic Bose con
- Page 31 and 32:
2. Properties of an atomic Bose con
- Page 33 and 34:
2. Properties of an atomic Bose con
- Page 35 and 36:
2. Properties of an atomic Bose con
- Page 37 and 38:
2. Properties of an atomic Bose con
- Page 39 and 40:
2. Properties of an atomic Bose con
- Page 41 and 42:
2. Properties of an atomic Bose con
- Page 43 and 44:
2. Properties of an atomic Bose con
- Page 45 and 46:
2. Properties of an atomic Bose con
- Page 47 and 48:
2. Properties of an atomic Bose con
- Page 49 and 50:
2. Properties of an atomic Bose con
- Page 51 and 52:
2. Properties of an atomic Bose con
- Page 53 and 54:
2. Properties of an atomic Bose con
- Page 55 and 56:
2. Properties of an atomic Bose con
- Page 57 and 58:
2. Properties of an atomic Bose con
- Page 59 and 60:
2. Properties of an atomic Bose con
- Page 62 and 63:
3. Homodyne measurements on a Bose-
- Page 64 and 65:
3. Homodyne measurements on a Bose-
- Page 66 and 67:
3. Homodyne measurements on a Bose-
- Page 68 and 69:
3. Homodyne measurements on a Bose-
- Page 70:
3. Homodyne measurements on a Bose-
- Page 75 and 76:
3. Homodyne measurements on a Bose-
- Page 77 and 78:
3. Homodyne measurements on a Bose-
- Page 79 and 80:
Chapter 4Continuously monitored con
- Page 81 and 82:
4. Continuously monitored Bose cond
- Page 83 and 84:
4. Continuously monitored Bose cond
- Page 85 and 86:
4. Continuously monitored Bose cond
- Page 87 and 88:
4. Continuously monitored Bose cond
- Page 89 and 90:
4. Continuously monitored Bose cond
- Page 91 and 92:
4. Continuously monitored Bose cond
- Page 93 and 94:
4. Continuously monitored Bose cond
- Page 95 and 96:
4. Continuously monitored Bose cond
- Page 97 and 98:
4. Continuously monitored Bose cond
- Page 99 and 100:
4. Continuously monitored Bose cond
- Page 101 and 102:
4. Continuously monitored Bose cond
- Page 103 and 104:
4. Continuously monitored Bose cond
- Page 105 and 106:
4. Continuously monitored Bose cond
- Page 107 and 108:
Chapter 5Weak force detection using
- Page 109 and 110:
5. Weak force detection using a dou
- Page 111 and 112:
5. Weak force detection using a dou
- Page 113 and 114:
5. Weak force detection using a dou
- Page 115 and 116:
5. Weak force detection using a dou
- Page 117 and 118:
5. Weak force detection using a dou
- Page 119 and 120:
5. Weak force detection using a dou
- Page 121 and 122:
5. Weak force detection using a dou
- Page 123 and 124:
Part IIQuantum evolution of a Bose
- Page 125 and 126:
6. Quantum effects in optical fibre
- Page 127 and 128:
6. Quantum effects in optical fibre
- Page 129 and 130:
6. Quantum effects in optical fibre
- Page 131 and 132:
6. Quantum effects in optical fibre
- Page 133 and 134:
6. Quantum effects in optical fibre
- Page 135 and 136:
6. Quantum effects in optical fibre
- Page 137 and 138:
6. Quantum effects in optical fibre
- Page 139 and 140:
6. Quantum effects in optical fibre
- Page 141 and 142: Chapter 7Quantum simulations of eva
- Page 143 and 144: 7. Quantum simulations of evaporati
- Page 145 and 146: 7. Quantum simulations of evaporati
- Page 147 and 148: 7. Quantum simulations of evaporati
- Page 149 and 150: 7. Quantum simulations of evaporati
- Page 151 and 152: 7. Quantum simulations of evaporati
- Page 153 and 154: 7. Quantum simulations of evaporati
- Page 155 and 156: 7. Quantum simulations of evaporati
- Page 157 and 158: 7. Quantum simulations of evaporati
- Page 159 and 160: 7. Quantum simulations of evaporati
- Page 161 and 162: 7. Quantum simulations of evaporati
- Page 163 and 164: 7. Quantum simulations of evaporati
- Page 165 and 166: 7. Quantum simulations of evaporati
- Page 167 and 168: 7. Quantum simulations of evaporati
- Page 169 and 170: 7. Quantum simulations of evaporati
- Page 171 and 172: A. Stochastic calculus in outlineco
- Page 173 and 174: Appendix BQuasiprobability distribu
- Page 175 and 176: B. Quasiprobability distributions u
- Page 177 and 178: Bibliography[1] Agrawal, G. P. Nonl
- Page 179 and 180: BIBLIOGRAPHY[22] Carter,S.J.Quantum
- Page 181 and 182: BIBLIOGRAPHY[45] Drummond, P. D., C
- Page 183 and 184: BIBLIOGRAPHY[68] Gordon,D.,andSavag
- Page 185 and 186: BIBLIOGRAPHY[92] Jaksch,D.,Gardiner
- Page 187 and 188: BIBLIOGRAPHY[114] Marshall, R. J.,
- Page 189 and 190: BIBLIOGRAPHY[135] Naraschewski, M.,
- Page 191: BIBLIOGRAPHY[158] Shelby, R. M., Le
- Page 195: . . . but this book is already too