Boundedness and exponential stabilization for time-space fractional parabolic-elliptic Keller-Segel model in higher dimensions
Abstract
For the time-space fractional degenerate Keller-Segel equation equation* cases ∂ tβ u=-(- )α2( (v)u),& t>0\\ (- )α2 v+v=u,& t>0 cases equation* x∈, ⊂ Rn, β∈ (0,1),α∈ (1,2), we consider for n≥ 3 the problem of finding a time-independent upper bound of the classical solution such that as θ>0,C>0 equation* \| u(· ,t)-u0 \|L∞ ( )+ \| v(· ,t)-u0 \|W1,∞ ( )≤ Ce(-θ)1/βt, equation* where u0=1 | |∫ u0dx. We find such solution in the special cases of time-independent upper bound of the concentration with Alikakos-Moser iteration and fractional differential inequality. In those cases the problem is reduced to a time-space fractional parabolic-elliptic equation which is treated with Lyapunov functional methods. A key element in our construction is a proof of the exponential stabilization toward the constant steady states by using fractional Duhamel type integral equation.
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