Book contents
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Bosons
- 3 Single-particle quantum mechanics
- 4 Classical stochastic systems
- 5 Bosonic fields
- 6 Dynamics of collisionless plasma
- 7 Kinetics of Bose condensates
- 8 Dynamics of phase transitions
- 9 Fermions
- 10 Quantum transport
- 11 Disordered fermionic systems
- 12 Mesoscopic effects
- 13 Electron–electron interactions in disordered metals
- 14 Dynamics of disordered superconductors
- References
- Index
4 - Classical stochastic systems
Published online by Cambridge University Press: 07 September 2011
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Bosons
- 3 Single-particle quantum mechanics
- 4 Classical stochastic systems
- 5 Bosonic fields
- 6 Dynamics of collisionless plasma
- 7 Kinetics of Bose condensates
- 8 Dynamics of phase transitions
- 9 Fermions
- 10 Quantum transport
- 11 Disordered fermionic systems
- 12 Mesoscopic effects
- 13 Electron–electron interactions in disordered metals
- 14 Dynamics of disordered superconductors
- References
- Index
Summary
This chapter is devoted to the classical limit of the quantum dissipative action obtained in Chapter 3. We show how it yields Langevin, Fokker–Planck and optimal path descriptions of classical stochastic systems. These approaches are used to discuss activation escape, fluctuation relation, reaction models and other examples.
Classical dissipative action
In Section 3.2 we derived the Keldysh action for a quantum particle coupled to an Ohmic environment, Eq. (3.20). If only linear terms in the quantum coordinate Xq(t) are kept in this action, it leads to a classical Newtonian equation with a viscous friction force, Eq. (3.21). Such an approximation completely disregards any fluctuations: both quantum and classical. Our goal now is to do better than that and to keep classical thermal fluctuations, while still neglecting quantum effects.
To this end it is convenient to restore the Planck constant ħ in the action and then take the limit ħ → 0. For dimensional reasons, the factor ħ-1 should stay in front of the entire action. To keep the part of the action responsible for the classical equation of motion (3.21) free from the Planck constant it is convenient to rescale the quantum component as Xq → ħXq. Indeed, when this is done all terms linear in Xq do not contain ħ. Finally, to have the temperature in energy units, one needs to substitute T with T/ħ.
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- Chapter
- Information
- Field Theory of Non-Equilibrium Systems , pp. 44 - 75Publisher: Cambridge University PressPrint publication year: 2011