Dynamics for the corotational energy-critical wave map equation with quantized blow-up rates
Abstract
We consider the wave maps from R1+2 into S2⊂ R3. Under an additional assumption of k-corotational symmetry, the problem reduces to the one dimensional semilinear wave equation: equation* ∂t2 u-∂r2 u-∂r ur+k2 (2u)2r2=0. equation* Given any integer k 1 and any integer m 2k, we exhibit a set of initial data (u0,u1) with energy arbitrarily close to that of the ground state solution Q, such that the corresponding solution u blows up in finite time by concentrating its energy. To be precise, the solution u satisfies equation* t→ T \|(u(t,r)-Q(rλ(t))-u1*(r), ∂t u-u2*(r))\|H× L2=0 equation* with a quantized speed equation* λ(t)=c(u0,u1)(1+ot T(1))(T-t)mk|(T-t)|mk(m-k), equation* where \|u\|H:=∫R2(|∂r u|2+|u|2r2).
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