Scattering theory for the defocusing fourth-order Schr\"odinger equation

Abstract

In this paper, we study the global well-posedness and scattering theory for the defocusing fourth-order nonlinear Schr\"odinger equation (FNLS) iut+2 u+|u|pu=0 in dimension d≥9. We prove that if the solution u is apriorily bounded in the critical Sobolev space, that is, u∈ Lt∞(I; Hscx(d)) with all sc:=d2-4p≥1 if p is an even integer or sc∈[1,2+p) otherwise, then u is global and scatters. The impetus to consider this problem stems from a series of recent works for the energy-supercritical and energy-subcritical nonlinear Schr\"odinger equation (NLS) and nonlinear wave equation (NLW). We will give a uniform way to treat the energy-subcritical, energy-critical and energy-supercritical FNLS, where we utilize the strategy derived from concentration compactness ideas to show that the proof of the global well-posedness and scattering is reduced to exclude the existence of three scenarios: finite time blowup; soliton-like solution and low to high frequency cascade. Making use of the No-waste Duhamel formula, we deduce that the energy or mass of the finite time blow-up solution is zero and so get a contradiction. Finally, we adopt the double Duhamel trick, the interaction Morawetz estimate and interpolation to kill the last two scenarios.