Prigogine–Defay ratio for systems with more than one order parameter
- 15 November 1976
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 65 (10), 4136-4140
- https://doi.org/10.1063/1.432870
Abstract
The Prigogine–Defay ratio, Π≡ΔCp Δκ/TV (Δα)2, has been derived for systems whose states need to be specified in terms of a number of order parameters z by considering the conditions of tangency of the equilibrium free energy surface and the free energy surface for constant values of the order parameters. It is shown that Π?1. The equality applies for the case of a single order parameter or for the case of more than one order parameter which satisfies the constraint (∂V/∂zi)/ (∂S/∂zi) = (∂V/∂zk)/(∂S/∂zk). The inequality applies for the case of more than one order parameter which does not satisfy this constraint. The relevance of the Prigogine–Defay ratio to the kinetics of the structural relaxation in glass is discussed.Keywords
This publication has 20 references indexed in Scilit:
- Validity of the Ehrenfest equation for a system with more than one ordering parameter: Critique of a paper by DiMarzioJournal of Applied Physics, 1975
- Strain relaxation in glass by optical correlation and pressure jump relaxationJournal of Applied Physics, 1975
- Validity of the Ehrenfest relation for a system with more than one order parameterJournal of Applied Physics, 1974
- Viscous liquids and the glass transition. IV. Thermodynamic equations and the transitionThe Journal of Physical Chemistry, 1973
- Degenerate Excited State in the Structure of B2O3The Journal of Chemical Physics, 1971
- Further studies in the annealing of a borosilicate glassJournal of Research of the National Bureau of Standards Section A: Physics and Chemistry, 1966
- Some Thermodynamic Aspects of the Glass Transition: Free Volume, Entropy, and Enthalpy TheoriesThe Journal of Chemical Physics, 1963
- The effect of pressure on glass temperature and dielectric relaxation time of polyvinyl acetateJournal of Polymer Science, 1962
- Thermodynamic and kinetic properties of glassesAdvances in Physics, 1953
- The irreversible approach to equilibrium in glassesProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1953