Asymptotic behavior of solutions to a singular chemotaxis system in multi-dimensions
Abstract
In this paper, we investigate the optimal large-time behavior of the global solution to a singular chemotaxis system in the whole space Rd with d=2,3. Assuming that the initial data is sufficiently close to an equilibrium state, we first prove the k-th order spatial derivative of the global solution converges to its corresponding equilibrium at the optimal rate (1+t)-(d4+k2), which improve upon the result in [37]. Then, for well-chosen initial data, we also establish lower bounds on the convergence rates, which match those of the heat equation. Our proof relies on a Cole-Hopf type transformation, delicate spectral analysis, the Fourier splitting technique, and energy methods.
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