On the Fremond’s constitutive model for shape memory alloys

In this work, we develop a non-local and thermo-mechanically-coupled constitutive model for polycrystalline shape-memory alloys (SMAs) capable of undergoing austenite $ martensite phase transformations. The theory is developed in the isotropic metal-plasticity setting using fundamental thermodynamic

In this paper we discuss the system of two partial di!erential equations governing the dynamics of phase transitions in shape memory alloys. We consider the one-dimensional model proposed by Falk, in which a term containing a fourth-derivative appears. The main purpose is to show the uniqueness for

Akstraet--We present a uniaxial model for shape-memory alloys, cast within the generalizedplasticity framework, previously developed. The model is based on two internal variables (the singlevariant martensite fraction and the multiple-variant martensite fraction), for which evolution equations in ra

An investigation into the computational aspects of a multi-well mixture approach to shape memory modeling is undertaken with the goals of determining its qualitative behavior as well as its eciency in a numerical setting. A basic rate dependent model for the transformation is ®rst introduced, follow

## Abstract A thermodynamic model describing pseudoelasticity is proposed. The kinematics are based on a self‐consistent Eulerian theory of finite deformations using the logarithmic rate. The thermomechanical state of the material is described by means of the mass fraction of martensite as internal