Global solvability and stabilization in multi-dimensional small-strain nonlinear thermoviscoelasticity

Abstract

Despite considerable developments in the literature of the past decades, a standing open problem in the analysis of continuum mechanics appears to consist of determining how far the prototypical model for small-strain thermoviscoelastic evolution in Kelvin-Voigt materials with inertia, as given by \[ utt = μ ut + (λ+μ)∇∇· ut + μ u + (λ+μ) ∇∇· u - B∇, t = D + μ |∇ ut|2 + (λ+μ) | div \, ut|2 - B div \, ut, () \] is globally solvable in multi-dimensional settings and for initial data of arbitrary size. The present manuscript addresses this in the context of an initial value problem in smoothly bounded n-dimensional domains with n 2, posed under homogeneous boundary conditions of Dirichlet type for the displacement variable u, and of Neumann type for the temperature . Within suitably generalized concepts of solvability, global existence of solutions is shown without any size restrictions on the data, and for a system actually more general than () by, inter alia, allowing the heat capacity to depend on . Apart from that, results on large time behavior are derived which particularly assert stabilization of toward a spatially homogeneous limit. Besides on standard features related to energy conservation and entropy production, in its core parts the analysis relies on an evolution property of certain logarithmic refinements of classical entropy functionals, to the best of our knowledge undiscovered in precedent literature and possibly of independent interest.