Decay of small energy solutions in the ABCD Boussinesq model under the influence of an uneven bottom

Abstract

The abcd Boussinesq system, introduced by Bona, Chen, and Saut, describes a four-parameter (a,b,c,d) family of models formulated on the time-space domain Rt × Rx. It serves as a first-order two-wave approximation to the two-dimensional incompressible, irrotational water wave equations in shallow water, inspired by Boussinesq's classical derivation. Within the different parameter regimes, the generic regime is described by b,d>0 and a,c<0 while the system becomes Hamiltonian when b=d. Previously, sharp local in space H1× H1 decay properties were proved in the case of a large class of abcd model under the small data assumption. In this paper, we generalize [C. Kwak, et. al., The scattering problem for Hamiltonian ABCD Boussinesq systems in the energy space. J. Math. Pures Appl. (9) 127 (2019), 121--159] by considering the small data abcd decay problem in the physically relevant variable bottom regime described by M. Chen. The nontrivial bathymetry is represented by a smooth space-time dependent function h=h(t,x), which obeys integrability in time and smallness in space. We prove first the existence of small global solutions in H1× H1. Then, for a sharp set of dispersive abcd systems (characterized only in terms of parameters a, b and c), every H1× H1 small solution must converges to zero inside of the light cone |x|≤ |t|.