Phase-field gradient theory

TL;DR

This paper develops a generalized phase-field gradient theory for enriched continua, incorporating second gradients, microtractions, and thermodynamic constraints, leading to new phase-field equations and boundary conditions.

Contribution

It introduces a comprehensive phase-field gradient theory based on microforce balances, including second gradients and microtractions, and generalizes existing phase-field models with thermodynamic consistency.

Findings

Derived generalized phase-field equations, including Swift-Hohenberg and phase-field crystal models.

Characterized microtraction fields and boundary conditions in enriched continua.

Ensured thermodynamic consistency of the proposed phase-field models.

Abstract

We propose a phase-field theory for enriched continua. To generalize classical phase-field models, we derive the phase-field gradient theory based on balances of microforces, microtorques, and mass. We focus on materials where second gradients of the phase field describe long-range interactions. By considering a nontrivial interaction inside the body, described by a boundary-edge microtraction, we characterize the existence of a microhypertraction field, a central aspect of this theory. On surfaces, we define the surface microtraction and the surface-couple microtraction emerging from internal surface interactions. We explicitly account for the lack of smoothness along a curve on surfaces enclosing arbitrary parts of the domain. In these rough areas, internal-edge microtractions appear. We begin our theory by characterizing these tractions. Next, in balancing microforces and microtorques, we arrive at the field equations. Subject to thermodynamic constraints, we develop a general set of constitutive relations for a phase-field model where its free-energy density depends on second gradients of the phase field. A priori, the balance equations are general and independent of constitutive equations, where the thermodynamics constrain the constitutive relations through the free-energy imbalance. To exemplify the usefulness of our theory, we generalize two commonly used phase-field equations. We propose a 'generalized Swift-Hohenberg equation'-a second-grade phase-field equation-and its conserved version, the 'generalized phase-field crystal equation'-a conserved second-grade phase-field equation. Furthermore, we derive the configurational fields arising in this theory. We conclude with the presentation of a comprehensive, thermodynamically consistent set of boundary conditions.