Type: Article
Publication Date: 2008-07-02
Citations: 86
DOI: https://doi.org/10.1093/amrx/abm004
For the 3D cubic nonlinear Schrödinger (NLS) equation, which has critical (scaling) norms L3 and Ḣ1/2, we first prove a result establishing sufficient conditions for global existence and sufficient conditions for finite-time blow-up. For the rest of the paper, we focus on the study of finite-time radial blow-up solutions, and prove a result on the concentration of the L3 norm at the origin. Two disparate possibilities emerge, one which coincides with solutions typically observed in numerical experiments that consist of a specific bump profile with maximum at the origin and focus toward the origin at rate ∼(T − t)1/2, where T > 0 is the blow-up time. For the other possibility, we propose the existence of “contracting sphere blow-up solutions,” that is, those that concentrate on a sphere of radius ∼(T − t)1/3, but focus toward this sphere at a faster rate ∼(T − t)2/3. These conjectured solutions are analyzed through heuristic arguments and shown (at this level of precision) to be consistent with all conservation laws of the equation.