A model for the deformations and thermodynamics of liquids involving a dislocation kinetics

Abstract

A model for the deformation and thermodynamics of liquids is developed that depends on dislocation kinetics. The approach uses concepts from statistical mechanics to model a stochastic evolution equation for a scalar dislocation density function. The dislocation density is used in an idealized model for the discrete discontinuous deformation due to dislocation motion and dislocation creation kinetics. The total deformation functional for a liquid is modelled as a continuum deformation of an idealized lattice structure plus the discontinuous deformation due to dislocation kinetics. This results in a thermodynamic model that has an elastic response from the continuum lattice structure and a fluid response from the dislocation kinetics. In the thermodynamics, a generalized internal energy functional is assumed to exist and to have a dependence on the functions of entropy, continuum lattice strain, scalar dislocation density, velocity, and mass density. The continuum lattice strain is termed the recoverable strain and its conjugate variable is the thermodynamic stress. The conjugate variable to the scalar dislocation density is the thermodynamic chemical potential for a dislocation configuration, somewhat analogous to Gibbs' treatment of chemical potential for various mass species. This model implies that a liquid and a crystalline solid have analogous deformation and thermodynamic responses. Their differences appear in the dislocation densities and in the dislocation chemical potentials. To illustrate the deformation response analogy, some solutions are developed for simple laminar shear flows. Also, using some concepts primarily from Kuhlmann-Wilsdorf's melting model, a definition for a specific dislocation creation heat equivalent is given. This thermodynamic formalism suggests that the melting process can be modelled as the consequence of a continuous change in the dislocation density function.