Book contents
- Frontmatter
- Dedication
- Contents
- Preface
- Acknowledgments
- 1 Introduction
- 2 Elements of magnetism
- 3 Elements of superconductivity
- 4 Brownian motion
- 5 Models for quantum dissipation
- 6 Implementation of the propagator approach
- 7 The damped harmonic oscillator
- 8 Dissipative quantum tunneling
- 9 Dissipative coherent tunneling
- 10 Outlook
- Appendix A Path integrals, the quantum mechanical propagator, and density operators
- Appendix B The Markovian master equation
- Appendix C Coherent-state representation
- Appendix D Euclidean methods
- References
- Index
4 - Brownian motion
Published online by Cambridge University Press: 05 April 2014
- Frontmatter
- Dedication
- Contents
- Preface
- Acknowledgments
- 1 Introduction
- 2 Elements of magnetism
- 3 Elements of superconductivity
- 4 Brownian motion
- 5 Models for quantum dissipation
- 6 Implementation of the propagator approach
- 7 The damped harmonic oscillator
- 8 Dissipative quantum tunneling
- 9 Dissipative coherent tunneling
- 10 Outlook
- Appendix A Path integrals, the quantum mechanical propagator, and density operators
- Appendix B The Markovian master equation
- Appendix C Coherent-state representation
- Appendix D Euclidean methods
- References
- Index
Summary
In the two preceding chapters of this book we have analyzed many interesting physical phenomena in magnetic and superconducting systems which could adequately be described by phenomenological dynamical equations in terms of collective classical variables. One unavoidable consequence of this approach is that, as we are always dealing with variables that describe only part of the whole system, the interaction with the remaining degrees of freedom shows up through the presence of non-conservative terms which describe the relaxation of those variables to equilibrium. Those phenomenological equations are able to describe a very rich diversity of physical phenomena, in particular, those which can be studied in the context of quantum mechanics. Since these are genuine dynamical equations, there is no reason why they should be restricted to classical physics. However, as we do not yet know how to treat dissipative effects in quantum mechanics, we have deliberately neglected those terms when trying to describe quantum mechanical effects of our collective variables.
In this chapter we will describe the general approach to dealing with dissipation in quantum mechanics. However, before we embark on this enterprise we should spend some time learning a little bit about the classical behavior of dissipative systems. In this way we can develop some intuition on how systems evolve during a dissipative process and, hopefully, this will be useful later on when we deal with quantum mechanical systems.
The immediate problem we have to face concerns the choice of dissipative system to be studied.
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- Publisher: Cambridge University PressPrint publication year: 2014