Resolvent Estimates for Viscoelastic Systems of Extended Maxwell Type and their Applications

TL;DR

This paper establishes resolvent estimates for the anisotropic extended Maxwell model in viscoelasticity, demonstrating the generation of semigroups and exponential decay of solutions, with implications for stability analysis.

Contribution

It introduces resolvent estimates for the extended Maxwell model, including augmented variables and reduced systems, proving semigroup generation and exponential decay of solutions.

Findings

The original and reduced systems generate $C_0$-groups and semigroups.

Solutions of the reduced system decay exponentially over time.

The energy estimate confirms stability and the limiting amplitude principle.

Abstract

In the theory of viscoelasticity, an important class of models admits a representation in terms of springs and dashpots. Widely used members of this class are the Maxwell model and its extended version. This paper concerns resolvent estimates for the system of equations for the anisotropic, extended Maxwell model, abbreviated as the EMM, and its marginal realization which includes an inertia term; special attention is paid to the introduction of augmented variables. This leads to the augmented system that will also be referred to as the "original" system. A reduced system is then formed which encodes essentially the EMM; it is a closed system with respect to the particle velocity and the difference between the elastic and viscous strains. Based on resolvent estimates, it is shown that the original and reduced systems generate $C_0$-groups and the reduced system generates a $C_0$-semigroup of contraction. Naturally, the EMM can be written in integrodifferential form leading explicitly to relaxation and a viscoelastic integro-differential system. However, there is a difference between the original and integrodifferential systems, in general, with consequences for whether their solutions generate semigroups or not. Finally, an energy estimate is obtained for the reduced system, and it is proven that its solutions decay exponentially as time tends to infinity. The limiting amplitude principle follows readily from these two results.