Book contents
- Frontmatter
- Contents
- Preface
- List of constants, conversions, and prefixes
- Part I Setting the scene
- Part II Small systems
- Part III Energy and the first law
- Part IV States and the second law
- Part V Constraints
- 9 Natural constraints
- 10 Models
- 11 Choice of variables
- 12 Special processes
- 13 Engines
- 14 Diffusive interactions
- Part VI Classical statistics
- Part VII Quantum statistics
- Appendices
- Further reading
- Problem solutions
- Index
14 - Diffusive interactions
from Part V - Constraints
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- List of constants, conversions, and prefixes
- Part I Setting the scene
- Part II Small systems
- Part III Energy and the first law
- Part IV States and the second law
- Part V Constraints
- 9 Natural constraints
- 10 Models
- 11 Choice of variables
- 12 Special processes
- 13 Engines
- 14 Diffusive interactions
- Part VI Classical statistics
- Part VII Quantum statistics
- Appendices
- Further reading
- Problem solutions
- Index
Summary
In Chapter 9 we showed that temperature governs thermal interactions, pressure governs mechanical interactions, and chemical potential governs diffusive interactions. They do this in ways that are so familiar to us that we call them “common sense”:
thermal interaction. Heat flows towards lower temperature.
mechanical interaction. Boundaries move towards lower pressure.
diffusive interaction. Particles go towards lower chemical potential.
In this chapter we examine diffusive interactions, working closely with the chemical potential μ and the Gibbs free energy N μ.
The chemical potential
In Chapter 5 we learned that the equilibrium distribution of particles is determined by the fact that particles seek configurations of
lower potential energy,
lower particle concentration.
Although the first of these is familiar in our macroscopic world (e.g., balls roll downhill), the second is due to thermal motions, which are significant only in the microscopic world (Figure 14.1).
Both factors trace their influence to the second law. The number of states per particle, and hence the entropy of the system, increases with increased volume in either momentum space or position space. Deeper potential wells release kinetic energy, making available more volume in momentum space, Vp. And lower particle concentrations mean more volume per particle in position space, Vr.
The two factors are interdependent. The preference for regions of lower potential energy affects particle concentrations, and vice versa. There is a trade-off. The reduction in one must more than offset the gain in the other (Figure 14.2).
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- An Introduction to Thermodynamics and Statistical Mechanics , pp. 287 - 326Publisher: Cambridge University PressPrint publication year: 2007