Blow-up of a hyperbolic equation of viscoelasticity with supercritical nonlinearities

Abstract

We investigate a hyperbolic PDE, modeling wave propagation in viscoelastic media, under the influence of a linear memory term of Boltzmann type, and a nonlinear damping modeling friction, as well as an energy-amplifying supercritical nonlinear source: align* cases utt- k(0) u - ∫0∞ k'(s) u(t-s) ds + |ut|m-1ut=|u|p-1u, \;\;\;\;\; × (0,T), \\ u(x,t)=u0(x,t), in × (-∞,0], cases align* where is a bounded domain in R3 with a Dirichl\'et boundary condition. The relaxation kernel k is monotone decreasing and k(∞)=1. We study blow-up of solutions when the source is stronger than dissipations, i.e., p> \m,k(0)\, under two different scenarios: first, the total energy is negative, and the second, the total energy is positive with sufficiently large quadratic energy. This manuscript is a follow-up work of the paper [30] in which Hadamard well-posedness of this equation has been established in the finite energy space. The model under consideration features a supercritical source and a linear memory that accounts for the full past history as time goes to -∞, which is distinct from other relevant models studied in the literature which usually involve subcritical sources and a finite-time memory.