Multidimensional Thermoelasticity for Nonsimple Materials -- Well-Posedness and Long-Time Behavior

TL;DR

This paper investigates the mathematical properties of a multidimensional thermoelasticity model for nonsimple materials, establishing well-posedness, stability conditions, and the effects of damping and hyperbolic relaxation.

Contribution

It provides new results on well-posedness, stability, and damping effects in multidimensional thermoelasticity for nonsimple materials with a center of symmetry.

Findings

Kelvin-Voigt and frictional damping influence stability

Lack of exponential stability without damping

Frictional damping induces exponential stability

Abstract

An initial-boundary value problem for the multidimensional type III thermoelaticity for a nonsimple material with a center of symmetry is considered. In the linear case, the well-posedness with and without Kelvin-Voigt and/or frictional damping in the elastic part as well as the lack of exponential stability in the elastically undamped case is proved. Further, a frictional damping for the elastic component is shown to lead to the exponential stability. A Cattaneo-type hyperbolic relaxation for the thermal part is introduced and the well-posedness and uniform stability under a nonlinear frictional damping are obtained using a compactness-uniqueness-type argument. Additionally, a connection between the exponential stability and exact observability for unitary $C_{0}$-groups is established.