Low-regularity global solution of the inhomogeneous nonlinear Schrödinger equations in modulation spaces (2410.00869v1)
Abstract: The study of low regularity Cauchy data for nonlinear dispersive PDEs has successfully been achieved using modulation spaces $M{p,q}$ in recent years. In this paper, we study the inhomogeneous nonlinear Schr\"odinger equation (INLS) $$iu_t + \Delta u\pm |x|{-b}|u|{\alpha}u=0,$$ where $\alpha, b>0,$ on whole space $\mathbb Rn$ in modulation spaces. In the subcritical regime $(0<\alpha< \frac{4-2b}{n}),$ we establish local well-posedness in $L{2}+M{\alpha+2,\frac{\alpha+2}{\alpha+1}}( \supset L2 + Hs \ \text{for} \ s>\frac{n\alpha}{2(\alpha+2)}).$ By adapting Bourgain's high-low decomposition method, we establish global well-posedness in $M{p,\frac{p}{p-1}}$ with $2<p$ and $p$ sufficiently close to 2. This is the first global well-posedness result for INLS on modulation spaces, which contains certain Sobolev $Hs$ $(0<s<1)$ and $Lp_s-$Sobolev spaces.