The pressureless damped Euler-Riesz system in the critical regularity framework

Abstract

We are concerned with a system governing the evolution of the pressureless compressible Euler equations with Riesz interaction and damping in Rd (d≥1), where the interaction force is given by ∇(-)α-d2(-) with d-2<α<d. Referring to the standard dissipative structure of first-order hyperbolic systems, the purpose of this paper is to investigate the weaker dissipation effect arising from the interaction force and to establish the global existence and large-time behavior of solutions to the Cauchy problem in the critical Lp framework. More precisely, it is observed by the spectral analysis that the density behaves like fractional heat diffusion at low frequencies. Furthermore, if the low-frequency part of the initial perturbation is bounded in some Besov space Bσ1p,∞ with -d/p-1≤ σ1<d/p-1, it is shown that the Lp-norm of the σ-order derivative for the density converges to its equilibrium at the rate (1+t)-σ-σ1α-d+2, which coincides with that of the fractional heat kernel.