A stability theory beyond the co-rotational setting for critical Wave Maps blow up

Abstract

We exhibit non-equivariant perturbations of the blowup solutions constructed in KST for energy critical wave maps into S2. Our admissible class of perturbations is an open set in some sufficiently smooth topology and vanishes near the light cone. We show that the blowup solutions from KST are rigid under such perturbations, including the space-time location of blowup. As blowup is approached, the dynamics agree with the classification obtained in DJKM, and all six symmetry parameters converge to limiting values. Compared to the previous work KMiao in which the rigidity of the blowup solutions from KST under equivariant perturbations was proved, the class of perturbations considered in the present work does not impose any symmetry restrictions. Separation of variables and decomposing into angular Fourier modes leads to an infinite system of coupled nonlinear equations, which we solve for small admissible data. The nonlinear analysis is based on the distorted Fourier transform, associated with an infinite family of Bessel type Schr\"odinger operators on the half-line indexed by the angular momentum~n. A semi-classical WKB-type spectral analysis relative to the parameter =1n+1 for large |n| allows us to effectively determine the distorted Fourier basis for the entire infinite family. Our linear analysis is based on the global Liouville-Green transform as in the earlier works CSST, CDST.