Blow-up for the 1D nonlinear Schrödinger equation with point nonlinearity I: Basic theory
arXiv:1510.03491
Abstract
We consider the 1D nonlinear Schrödinger equation (NLS) with focusing point nonlinearity, $$ (δ\text{NLS}) \qquad i\partial_tÏ+ \partial_x^2Ï+ δ|Ï|^{p-1}Ï= 0, $$ where $δ=δ(x)$ is the delta function supported at the origin. We show that $δ$NLS shares many properties in common with those previously established for the focusing autonomous translationally-invariant NLS $$ (\text{NLS}) \qquad i\partial_t Ï+ ÎÏ+ |Ï|^{p-1}Ï=0 \,. $$ The critical Sobolev space $\dot H^{Ï_c}$ for $δ$NLS is $Ï_c=\frac12-\frac{1}{p-1}$, whereas for NLS it is $Ï_c=\frac{d}{2}-\frac{2}{p-1}$. In particular, the $L^2$ critical case for $δ$NLS is $p=3$. We prove several results pertaining to blow-up for $δ$NLS that correspond to key classical results for NLS. Specifically, we (1) obtain a sharp Gagliardo-Nirenberg inequality analogous to Weinstein (1983), (2) apply the sharp Gagliardo-Nirenberg inequality and a local virial identity to obtain a sharp global existence/blow-up threshold analogous to Weinstein (1983), Glassey (1977) in the case $Ï_c=0$ and Duyckaerts, Holmer, & Roudenko (2008), Guevara (2014), and Fang, Xie, & Cazenave (2011) for $0<Ï_c<1$, (3) prove a sharp mass concentration result in the $L^2$ critical case analogous to Tsutsumi (1990), Merle & Tsutsumi (1990) and (4) show that minimal mass blow-up solutions in the $L^2$ critical case are pseudoconformal transformations of the ground state, analogous to Merle (1993).
22 pages, 1 figure