Large time existence in a thermoviscoelastic evolution problem with mildly temperature-dependent parameters

Abstract

We consider align* HS \ arrayl utt = (γ() uxt)x + a (γ() ux)x +(f())x, \\[1mm] t = Dxx + () uxt2 + F() uxt, array. () align* under Neumann boundary conditions for u and Dirichlet boundary conditions for in a bounded interval ⊂R. This model is a generalization of the classical system for the description of strain and temperature evolution in a thermo-viscoelastic material following a Kelvin-Voigt material law, in which γ and f F. Different variations of this model have already been analyzed in the past and the present study draws upon a known result concerning the existence of classical solutions, which are local in time, for suitably smooth initial data, arbitrary a>0, D>0 and γ,f∈ C2([0,∞)) as well as ,F∈ C1([0,∞)) with γ>0,0 and F(0)=0. Our work focuses on proving that existence times for classical solutions can be arbitrarily large, assuming sublinear temperature dependencies of γ and f, and further |F(s)| CF(1+s)α for some CF>0 and α∈(0,1). In particular, for any given T, initial mass M and 0<γ<γ, there exists a constant δ(M,T,a,D, , γ, γ,CF,α)>0, such that if γ γ γ and 0 γ as well as \|γ'\|L∞([0,∞)) δ and \|f'\|L∞([0,∞)) δ hold, the maximal existence time of the classical solution to () surpasses T.