Energy Distribution of Radial Solutions to Energy Subcritical Wave Equation with an Application on Scattering Theory

Abstract

The topic of this paper is a semi-linear, energy sub-critical, defocusing wave equation ∂t2 u - u = - |u|p -1 u in the 3-dimensional space (3≤ p<5) whose initial data are radial and come with a finite energy. We split the energy into inward and outward energies, then apply energy flux formula to obtain the following asymptotic distribution of energy: Unless the solution scatters, its energy can be divided into two parts: "scattering energy" which concentrates around the light cone |x|=|t| and moves to infinity at the light speed and "retarded energy" which is at a distance of at least |t|β behind when |t| is large. Here β is an arbitrary constant smaller than β0(p) = 2(p-2)p+1. A combination of this property with a more detailed version of the classic Morawetz estimate gives a scattering result under a weaker assumption on initial data (u0,u1) than previously known results. More precisely, we assume \[ ∫ R3 (|x|+1)(12|∇ u0|2 + 12|u1|2+1p+1|u|p+1) dx < +∞. \] Here >0(p) =1-β0(p) = 5-pp+1 is a constant.