On the stability of type II blowup for the 1-corotational energy supercritical harmonic heat flow

Abstract

We consider the energy supercritical harmonic heat flow from Rd into the d-sphere Sd with d ≥ 7. Under an additional assumption of 1-corotational symmetry, the problem reduces to the one dimensional semilinear heat equation ∂t u = ∂2r u + (d-1)r∂r u - (d-1)2r2(2u). We construct for this equation a family of C∞ solutions which blow up in finite time via concentration of the universal profile u(r,t) Q(rλ(t)), where Q is the stationary solution of the equation and the speed is given by the quantized rates λ(t) cu(T-t)γ, ∈ N*, \;\; 2 > γ = γ(d) ∈ (1,2]. The construction relies on two arguments: the reduction of the problem to a finite-dimensional one thanks to a robust universal energy method and modulation techniques developed by Merle, Rapha\"el and Rodnianski [Camb. Jour. Math, 3(4):439-617, 2015] for the energy supercritical nonlinear Schr\"odinger equation and by Rapha\"el and Schweyer [Anal. PDE, 7(8):1713-1805, 2014] for the energy critical harmonic heat flow, then we proceed by contradiction to solve the finite-dimensional problem and conclude using the Brouwer fixed point theorem. Moreover, our constructed solutions are in fact ( - 1) codimension stable under perturbations of the initial data. As a consequence, the case = 1 corresponds to a stable type II blowup regime.