Mode stability for self-similar blowup of slightly supercritical NLS: I. low-energy spectrum

TL;DR

This paper proves mode stability for the low-energy spectrum of self-similar blowup solutions in slightly supercritical nonlinear Schrödinger equations, using advanced spectral and asymptotic analysis techniques.

Contribution

It establishes the mode stability of the low-energy spectrum for the linearized operator around ground states in the supercritical NLS, extending previous work to a broader setting.

Findings

Proved mode stability for the low-energy spectrum in all dimensions.

Developed a novel combination of Jost function, WKB, and matched asymptotics methods.

Provided uniform estimates for high spherical classes using special functions.

Abstract

We consider self-similar blowup for (NLS) $i\partial_t u + \Delta u + u|u|^{p-1} = 0$ in $d \ge 1$ and slightly mass-supercritical range $0 < s_c := \frac d2 - \frac{2}{p-1} \ll 1$. The existence and stability of such dynamics [Merle-Rapha\"el-Szeftel, 2010] and construction of suitable profiles [Bahri-Martel-Rapha\"el, 2021] lead to the question of asymptotic stability. Based on our previous work [Li, 2023], this nonlinear problem is reduced to linear mode stability of the matrix linearized operator. In this work, we prove mode stability for the low-energy spectrum in $d \ge 1$ as a perturbation of the linearized operator around ground state for mass-critical NLS. The main difficulty of this spectral bifurcation problem arises from the non-self-adjoint, relatively unbounded and high-dimensional nature, for which we exploit the Jost function argument from [Perelman, 2001], qualitative WKB analysis generalized from [Bahri-Martel-Rapha\"el, 2021], matched asymptotics method and uniform estimates for high spherical classes based on special functions.