Quantized slow blow up dynamics for the corotational energy critical harmonic heat flow

Abstract

We consider the energy critical harmonic heat flow from R2 into a smooth compact revolution surface of R3. For initial data with corotational symmetry, the evolution reduces to the semilinear radially symmetric parabolic problem ∂t u -2r u-r ur + f(u)r2=0 for a suitable class of functions f . Given an integer L∈ N*, we exhibit a set of initial data arbitrarily close to the least energy harmonic map Q in the energy critical topology such that the corresponding solution blows up in finite time by concentrating its energy ∇ u(t,r)-∇ Q(r(t)) u* in L2 at a speed given by the quantized rates: (t)=c(u0)(1+o(1))(T-t)L| (T-t)|2L2L-1, in accordance with the formal predictions [3]. The case L=1 corresponds to the stable regime exhibited in [37], and the data for L 2 leave on a manifold of codimension (L-1) in some weak sense. Our analysis lies in the continuation of [36,32,37] by further exhibiting the mechanism for the existence of the excited slow blow up rates and the associated instability of these threshold dynamics.