Exponential growth of solution with Lp-norm for class of non-linear viscoelastic wave equation with distributed delay term for large initial data

Abdelbaki Choucha1,∗ Djamel Ouchenane2 and Khaled Zennir3 1 Department of Mathematics, Faculty of Exact Sciences, University of El Oued, B.P. 789, El Oued 39000, Algeria. 2 Laboratory of pure and applied Mathematics, Amar Teledji Laghouat University, Algeria. 3 Department of Mathematics, College of Sciences and Arts, Qassim University, Ar-Rass, Saudi Arabia. * Correspondence: abdelbaki.choucha@gmail.com


Introduction
T he well known "Growth" phenomenon is one of the most important phenomena of asymptotic behavior, where many researches omit from its study especially when it comes from the evolution problems. It gives us very important information to know the behavior of equation when time arrives at infinity, it differs from global existence and blow up in both mathematically and in applications point of view. Although the interest of the scientific community for the study of delayed problems is fairly recent, multiple techniques have already been explored in depth.
In this direction, we are concerned with the delayed damped system where ω, b, µ 1 are positive constants, p > 2 and τ 1 , τ 2 are the time delay with 0 ≤ τ 1 < τ 2 and µ 2 is bounded function and is a differentiable function. It is well known that viscous materials are the opposite of elastic materials which have the capacity to store and dissipate mechanical energy. As the mechanical properties of these viscous substances are of great importance when they appear in many applications of other applied sciences. Many searchers have paid attention to this problem.
In the absence of the strong damping ∆u t , that is for w = 0 and in absence of the distributed delay term. Our problem (1) has been investigated by many authors and results on the local/global existence, and stability have been established. See for example [1][2][3][4]. In [5], the authors looked into the following system where decay result of an exponential rate was showed. In [6], Song and Xue considered with the following viscoelastic equation with strong damping: The authors showed, under suitable conditions on g, that there were solutions of (3) with arbitrarily high initial energy that blow up in a finite time. For the same Problem (3), in [7], Song and Zhong showed that there were solutions of (3) with positive initial energy that blew up in finite time. In [8], Zennir considered with the following viscoelastic equation with strong damping: They proved the exponential growth result under suitable assumptions. In [9] the authors considered the following problem for a nonlinear viscoelastic wave equation with strong damping, nonlinear damping and source terms They proved a blow up result if p > m and established the global existence. In this article, we investigated Problem (1), in which all the damping mechanism have been considered in the same time, these assumptions make our problem different form those studied in the literature, specially the Exponential Growth of solutions. We will prove that if the initial energy E(0) of our solutions is negative (this means that our initial data are large enough), then our local solutions in bounded and as t tends to ∞, used idea in [10][11][12][13].
Our aim in the present work is to extend the existing exponential growth results to strong damping for a viscoelastic problem with distributed delay under the following assumptions: (A2) There exists a constant ξ > 0 such that

Main results
First, as in [14], we introduce the new variable Let us denote by Therefore, Problem (1) takes the form with initial and boundary conditions where We state without proof the local existence theorem that can be established by combining arguments of [15]. Theorem 1. Assume (7), (8) and (9) holds. Let Then for any initial data with compact support, Problem (13) has a unique solution u ∈ C([0, T]; H), for some T > 0.
In the next theorem we give the global existence result, its proof based on the potential well depth method in which the concept of so-called stable set appears, where we show that if we restrict our initial data in the stable set, then our local solution obtained is global in time. One can make use of arguments in [16].
At this point, we choose a > 0 so small that then we choose κ so large that