Analysis of a thermoelastic problem with the Moore–Gibson–Thompson microtemperatures
DATE:
2024-03
UNIVERSAL IDENTIFIER: http://hdl.handle.net/11093/6330
EDITED VERSION: https://linkinghub.elsevier.com/retrieve/pii/S0377042723005150
DOCUMENT TYPE: article
ABSTRACT
In this paper, we study, from both an analytical and a numerical point of view, a poro-thermoelastic problem with microtemperatures. The so-called Moore–Gibson–Thompson equation is used to model the contribution for the temperature and microtemperatures. An existence and uniqueness result is proved by using the theory of linear semigroups of contractions and, for the one-dimensional case, the exponential energy decay is found under some conditions on the constitutive coefficients. Then, a fully discrete approximation is introduced by using the finite element method and the implicit Euler scheme. We show that the discrete energy decays and we obtain some a priori error estimates from which, under some adequate additional regularity conditions on the continuous solution, we derive the linear convergence of the approximations. Finally, we perform some numerical simulations to demonstrate the accuracy of the approximations and the behavior of the discrete energy and the solution.