Existence of finite time blow-up in Keller-Segel system
Abstract
Perhaps the most classical diffusion model for chemotaxis is the Keller-Segel system equation cases ut = u - ∇ ·(u ∇ v) \ \ \ in R2×(0,T),\\[5pt] v = (-R2)-1 u := 12π ∫R2 1|x-z|u(z,t) dz, \ \ \ \ \ \ \ \ \ ()\\[5pt] u(· ,0) = u0 0 \ \ \ in R2. cases equation We show that there exists >0 such that for any m satisfying 8π<m 8π+ and any k given points q1,...,qk in R2 there is an initial data u0* of () for which the solution u(x,t) blows-up in finite time as t T with the approximate profile u(x,t)=Σj=1k1λj2(t)U(x-j(t)λj(t))(1+o(1)), U(y)=8(1+|y|2)2, with λj(t) ≈ 2e-γ+22T-te-|(T-t)|2 where γ=0.57721... is the Euler-Mascheroni constant, j(t) qj∈ R2 and such that ∫R2u(x,t)dx=km. This construction generalizes the existence result of the stable blow-up dynamics recently proved in CGMN1,CGMN2.
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