Global solutions and large time stabilization in a model for thermoacoustics in a standard linear solid

Abstract

This manuscript is concerned with the one-dimensional system \[ arrayl τ uttt + α utt = b (γ() uxt)x + ( γ() ux)x, \\[1mm] t = D xx + bγ() uxt2, array \] which is connected to the simplified modeling of heat generation in Zener type materials subject to stress from acoustic waves. Under the assumption that the coefficients τ>0, b>0 and α≥0 satisfy align α b >τ, align it is shown that for all >0 one can find =(D,τ,α,b,,γ)>0 such that an associated Neumann type initial-boundary value problem with Neumann data admits a unique time-global solution in a suitable framework of strong solvability whenever the initial temperature distribution fulfills \|0\|L∞()≤ and the derivatives of the initial data are sufficiently small in the sense of satisfying ∫ u0xx2 + ∫ (u0t)xx2 + ∫ (u0tt)x2 < \|0x\|L∞() + \|0xx\|L∞() < . The constructed solution moreover features an exponential stabilization property for both components. In particular, the parameter range described by () coincides with the full stability regime known for the corresponding Moore--Gibson--Thompson equation despite the fairly strong nonlinear coupling to the temperature variable.