Approaching optimality in blow-up results for Keller-Segel systems with logistic-type dampening

Abstract

Nonnegative solutions of the Neumann initial-boundary value problem for the chemotaxis system alignprob:star cases ut = u - ∇ · (u ∇ v) + λ u - μ u, \\\\ 0 = v - m(t) + u, m(t) = 1|| ∫ u(·, t) cases align in smooth bounded domains ⊂ Rn, n 1, are known to be global-in-time if λ ≥ 0, μ > 0 and > 2. In the present work, we show that the exponent = 2 is actually critical in the four- and higher dimensional setting. More precisely, if alignat*3 n &≥ 4, && ∈ (1, 2) &&and μ > 0 \\\\ or n &≥ 5, && = 2 &&and μ ∈ (0, n-4n), alignat* for balls ⊂ Rn and parameters λ ≥ 0, m0 > 0, we construct a nonnegative initial datum u0 ∈ C0( ) with ∫ u0 = m0 for which the corresponding solution (u, v) of prob:star blows up in finite time. Moreover, in 3D, we obtain finite-time blow-up for ∈ (1, 32) (and λ ≥ 0, μ > 0). As the corner stone of our analysis, for certain initial data, we prove that the mass accumulation function w(s, t) = ∫0[n]s n-1 u(, t) \, d fulfills the estimate ws ws. Using this information, we then obtain finite-time blow-up of u by showing that for suitably chosen initial data, s0 and γ, the function φ(t) = ∫0s0 s-γ (s0 - s) w(s, t) cannot exist globally.