Book contents
- Frontmatter
- Contents
- Preface
- 1 Thermostatics
- 2 Statistical entropy and Boltzmann distribution
- 3 Canonical and grand canonical ensembles: applications
- 4 Critical phenomena
- 5 Quantum statistics
- 6 Irreversible processes: macroscopic theory
- 7 Numerical simulations
- 8 Irreversible processes: kinetic theory
- 9 Topics in non-equilibrium statistical mechanics
- Appendix
- References
- Index
1 - Thermostatics
Published online by Cambridge University Press: 03 December 2009
- Frontmatter
- Contents
- Preface
- 1 Thermostatics
- 2 Statistical entropy and Boltzmann distribution
- 3 Canonical and grand canonical ensembles: applications
- 4 Critical phenomena
- 5 Quantum statistics
- 6 Irreversible processes: macroscopic theory
- 7 Numerical simulations
- 8 Irreversible processes: kinetic theory
- 9 Topics in non-equilibrium statistical mechanics
- Appendix
- References
- Index
Summary
The goal of this first chapter is to give a presentation of thermodynamics, due to H. Callen, which will allow us to make the most direct connection with the statistical approach of the following chapter. Instead of introducing entropy by starting with the second law, for example with the Kelvin statement ‘there exists no transformation whose sole effect is to extract a quantity of heat from a reservoir and convert it entirely to work’, Callen assumes, in principle, the existence of an entropy function and its fundamental property: the principle of maximum entropy. Such a presentation leads to a concise discussion of the foundations of thermodynamics (at the cost of some abstraction) and has the advantage of allowing direct comparison with the statistical entropy that we shall introduce in Chapter 2. Clearly, it is not possible in one chapter to give an exhaustive account of thermodynamics; the reader is, instead, referred to classic books on the subject for further details.
Thermodynamic equilibrium
Microscopic and macroscopic descriptions
The aim of statistical thermodynamics is to describe the behaviour of macroscopic systems containing of the order of N ≈ 1023 particles. An example of such a macroscopic system is a mole of gas in a container under standard conditions of temperature and pressure. This gas has 6 × 1023 molecules in incessant motion, continually colliding with each other and with the walls of the container. To a first approximation, which will be justified in Chapter 2, we may consider these molecules as classical objects.
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- Publisher: Cambridge University PressPrint publication year: 2004