Thermodynamically consistent continuum dislocation dynamics

TL;DR

This paper develops a thermodynamically consistent continuum dislocation dynamics model that incorporates new stress contributions from dislocation curvature, enhancing the understanding of dislocation behavior in materials.

Contribution

It introduces a free energy-based approach to derive a thermodynamically consistent dislocation velocity in continuum dislocation dynamics, including new stress terms from dislocation curvature.

Findings

Identifies a new stress contribution from dislocation curvature.

Derives a dislocation velocity incorporating five stress contributions.

Demonstrates thermodynamic consistency in continuum dislocation modeling.

Abstract

Dislocation based modeling of plasticity is one of the central challenges at the crossover of materials science and continuum mechanics. Developing a continuum theory of dislocations requires the solution of two long standing problems: (i) to represent dislocation kinematics in terms of a reasonable number of variables and (ii) to derive averaged descriptions of the dislocation dynamics (i.e. material laws) in terms of these variables. The kinematic problem (i) was recently solved through the introduction of continuum dislocation dynamics (CDD), which provides kinematically consistent evolution equations of dislocation alignment tensors, presuming a given average dislocation velocity (Hochrainer (2015), Philos. Mag. 95 (12), 1321--1367). In the current paper we demonstrate how a free energy formulation may be used to solve the dynamic closure problem (ii) in CDD. We do so exemplarily for the lowest order CDD variant for curved dislocations in a single slip situation. In this case, a thermodynamically consistent average dislocation velocity is found to comprise five mesoscopic shear stress contributions. For a postulated free energy expression we identify among these stress contributions a back-stress term and a line-tension term, both of which have already been postulated for CDD. A new stress contribution occurs which is missing in earlier CDD models including the statistical continuum theory of straight parallel edge dislocations (Groma et al. (2015), Acta Mater. 51, 1271-1281). Furthermore, two entirely new stress contributions arise from the curvature of dislocations.