This book aims to provide a theoretical framework for understanding the physics of degenerate quantum gases. It contains detailed derivations of all the key results and includes chapters covering necessary background mathematics, with many exercises being provided for readers who wish to check their understanding.
This book aims to provide a theoretical framework for understanding the physics of degenerate quantum gases. It contains detailed derivations of all the key results and includes chapters covering necessary background mathematics, with many exercises being provided for readers who wish to check their understanding.
Bryan Dalton obtained a PhD degree in 1966 from Monash University. Following postdoctoral positions at University of Chicago and Australian National University, he joined the Department of Physics, University of Queensland in 1970, retiring as a Reader in 2000. His research was in theoretical quantum optics on topics such as non-classical states of light, coherent population trapping, laser-induced continuum structures, quantum beats, squeezed light spectroscopy and macroscopic cavity quantum electrodynamics. After 2000, he held research fellow positions at University of Sussex and Swinburne University of Technology, where he is currently an Adjunct Professor. He recently spent six months at University College, Cork as an ETS Walton Visiting Fellow. His more recent research interests have included decoherence effects in quantum computers, phase space theory in quantum and atom optics for Bose-Einstein condensates and Fermi gases, and entanglement theory for identical particle systems. John Jeffers is a Reader in the Physics Department at the University of Strathclyde and has been a researcher in quantum optics for twenty years. He obtained his PhD in Theoretical Physics from the University of Essex in 1993. Since then his research interests have included quantum dielectrics, quantum imaging, retrodictive quantum theory, quantum communication, quantum optical amplification and degenerate quantum gases. Stephen Barnett has been Professor of Quantum Optics since 1995, first at the University of Strathclyde and more recently at the University of Glasgow. He is best known for his discovery, with David Pegg, of the quantum phase operator, but he has wide-spread interests in quantum optics, quantum information, optics and, of course, cold-atom physics. His work has been recognised by the Royal Society, the Royal Society of Edinburgh and the Optical Society of America, all of which have elected him a Fellow. He was awarded the 2013 Dirac Medal and Prize for theoretical physics by the Institute of Physics.
Inhaltsangabe
1: Introduction 2: States and Operators 3: Complex Numbers and Grassmann Numbers 4: Grassmann Calculus 5: Coherent States 6: Canonical Transformations 7: Phase Space Distributions 8: Fokker-Planck Equations 9: Langevin Equations 10: Application to Few Mode Systems 11: Functional Calculus for C-Number and Grassmann Fields 12: Distribution Functionals in Quantum-Atom Optics 13: Functional Fokker-Planck Equations 14: Langevin Field Equations 15: Application to Multi-Mode Systems 16: Further Developments Appendix A: Fermion Anti-Commutation Rules Appendix B: Markovian Master Equation Appendix C: Grassmann Calculus Appendix D: Properties of Coherent States Appendix E: Phase Space Distributions for Bosons and Fermions Appendix F: Fokker-Planck Equations Appendix G: Langevin Equations Appendix H: Functional Calculus for Restricted Boson and Fermion Fields Appendix I: Applications to Multi-Mode Systems
1: Introduction 2: States and Operators 3: Complex Numbers and Grassmann Numbers 4: Grassmann Calculus 5: Coherent States 6: Canonical Transformations 7: Phase Space Distributions 8: Fokker-Planck Equations 9: Langevin Equations 10: Application to Few Mode Systems 11: Functional Calculus for C-Number and Grassmann Fields 12: Distribution Functionals in Quantum-Atom Optics 13: Functional Fokker-Planck Equations 14: Langevin Field Equations 15: Application to Multi-Mode Systems 16: Further Developments Appendix A: Fermion Anti-Commutation Rules Appendix B: Markovian Master Equation Appendix C: Grassmann Calculus Appendix D: Properties of Coherent States Appendix E: Phase Space Distributions for Bosons and Fermions Appendix F: Fokker-Planck Equations Appendix G: Langevin Equations Appendix H: Functional Calculus for Restricted Boson and Fermion Fields Appendix I: Applications to Multi-Mode Systems
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