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
Preface
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
On deciding to write this book, I had two main worries: firstly, what audience it would reach and secondly, to avoid as far as possible overlaps with other excellent texts already existing in the literature.
Regarding the first issue I have noticed, when discussing with colleagues, super-vising students, or teaching courses on the subject, that there is a gap between the standard knowledge on the conventional areas of physics and the way macroscopic quantum phenomena and quantum dissipation are presented to the reader. Usually, they are introduced through phenomenological equations of motion for the appropriate dynamical variables involved in the problem which, if we neglect dissipative effects, are quantized by canonical methods. The resulting physics is then interpreted by borrowing concepts of the basic areas involved in the problem – which are not necessarily familiar to a general readership – and adapted to the particular situation being dealt with. The so-called macroscopic quantum effects arise when the dynamical variable of interest, which is to be treated as a genuine quantum variable, refers to the collective behavior of an enormous number of microscopic (atomic or molecular) constituents. Therefore, if we want it to be appreciated even by more experienced researchers, some general background on the basic physics involved in the problem must be provided.
In order to ill this gap, I decided to start the presentation of the book by introducing some very general background on subjects which are emblematic of macroscopic quantum phenomena: magnetism and superconductivity.
- Type
- Chapter
- Information
- Publisher: Cambridge University PressPrint publication year: 2014