Describing smooth small-data solutions to a quasilinear hyperbolic-parabolic system by W1,p energy analysis

Abstract

In bounded n-dimensonal domains with n 1, this manuscript examines an initial-boundary value problem for the system \[ \ arrayl utt = ∇ · (γ() ∇ ut) + a ∇ · (γ() ∇ u) + ∇· f(), t = D + () |∇ ut|2 + F()· ∇ ut, array . \] which in the case n=1 and with γ as well as f F reduces to the classical model for the evolution of strains and temperatures in thermoviscoelasticity. Unlike in previous related studies, the focus here is on situations in which besides f and F, also the core ingredients γ and may depend on the temperature variable . Firstly, a statement on local existence of classical solutions is derived for arbitrary a>0, D>0 as well as 0<γ∈ C2([0,∞)) and 0∈ C1([0,∞)), for functions f∈ C2([0,∞);Rn) and F∈ C1([0,∞);Rn) with F(0)=0, and for suitably regular initial data of arbitrary size. Secondly, it is seen that for each p 2 such that p>n there exists δ(p)>0 with the property that whenever in addition to the above we have \[ aγ(0) δ(p) and |f'()| · |F()|D · γ() δ(p), \] for initial data suitably close to the constant level given by u=0 and =, with any fixed 0, these solutions are actually global in time and have the property that ∇ ut, ∇ u and ∇ decay exponentially fast in Lp. This is achieved by detecting suitable dissipative properties of functionals involving norms of these gradients in Lp spaces.

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