Book contents
- Frontmatter
- Contents
- Preface
- Acknowledgements
- 1 Statistical physics of liquids
- 2 The freezing transition
- 3 Crystal nucleation
- 4 The supercooled liquid
- 5 Dynamics of collective modes
- 6 Nonlinear fluctuating hydrodynamics
- 7 Renormalization of the dynamics
- 8 The ergodic–nonergodic transition
- 9 The nonequilibrium dynamics
- 10 The thermodynamic transition scenario
- References
- Index
3 - Crystal nucleation
Published online by Cambridge University Press: 07 September 2011
- Frontmatter
- Contents
- Preface
- Acknowledgements
- 1 Statistical physics of liquids
- 2 The freezing transition
- 3 Crystal nucleation
- 4 The supercooled liquid
- 5 Dynamics of collective modes
- 6 Nonlinear fluctuating hydrodynamics
- 7 Renormalization of the dynamics
- 8 The ergodic–nonergodic transition
- 9 The nonequilibrium dynamics
- 10 The thermodynamic transition scenario
- References
- Index
Summary
If the liquid is cooled beyond the corresponding freezing point Tm at which the liquid and crystalline phases coexist in equilibrium, a thermodynamic driving force builds up towards forming the crystal. In this chapter we will discuss how the liquid transforms into a crystal, focusing on how the changes in the liquid are initiated and on the nature of the crystalline region that is formed. This process is referred to as nucleation. The thermodynamic force favoring the formation of the crystal seed in the supercooled liquid competes with the process of forming an interface between the solid and the liquid. The cost of the interfacial free energy therefore presents a barrier to the formation of the new phase. Only when the driving force is made large enough by moving deep into the supercooled state does crystallization occur on laboratory time scales. Thus pure water can be cooled to -20 °C or below without freezing. Our focus here will be mainly on the process of crystallization of solid from the melt. The condensation of vapor into liquid is a very thoroughly studied process that has been discussed in various reviews (Stanley, 1971; Evans, 1979; ten Wolde et al., 1998). For condensation from a low-density gas or crystallization from dilute solution, it is easier to identify the nucleating bubbles since they differ widely in composition from the surrounding phase.
- Type
- Chapter
- Information
- Statistical Physics of Liquids at Freezing and Beyond , pp. 117 - 163Publisher: Cambridge University PressPrint publication year: 2011