Asymptotic limit and decay estimates for a class of dissipative linear hyperbolic systems in several dimensions

Abstract

In this paper, we study the large-time behavior of solutions to a class of partially dissipative linear hyperbolic systems with applications in velocity-jump processes in several dimensions. Given integers n,d 1, let A:=(A1,…,Ad)∈ ( Rn× n)d be a matrix-vector, where Aj∈ Rn× n, and let B∈ Rn× n be not required to be symmetric but have one single eigenvalue zero, we consider the Cauchy problem for linear n× n systems having the form equation* ∂tu+ A· ∇ x u+Bu=0, ( x,t)∈ Rd× R+. equation* Under appropriate assumptions, we show that the solution u is decomposed into u=u(1)+u(2), where u(1) has the asymptotic profile which is the solution, denoted by U, of a parabolic equation and u(1)-U decays at the rate t- d2( 1q- 1p)- 12 as t +∞ in any Lp-norm, and u(2) decays exponentially in L2-norm, provided u(·,0)∈ Lq( Rd) L2( Rd) for 1 q p ∞. Moreover, u(1)-U decays at the optimal rate t- d2( 1q- 1p)-1 as t +∞ if the system satisfies a symmetry property. The main proofs are based on asymptotic expansions of the solution u in the frequency space and the Fourier analysis.