Optimal decay rates and space-time analyticity of solutions to the Patlak-Keller-Segel equations

Abstract

Based on some elementary estimates for the space-time derivatives of the heat kernel, we use a bootstrapping approach to establish the optimal decay rates for the Lq(Rd) (1≤ q≤∞, d∈N) norm of the space-time derivatives of solutions to the (modified) Patlak-Keller-Segel equations with initial data in L1(Rd), which implies the joint space-time analyticity of solutions. When the L1(Rd) norm of the initial datum is small, the upper bound for the decay estimates is global in time, which yields a lower bound on the growth rate of the radius of space-time analyticity in time. As a byproduct, the space analyticity is obtained for any initial data in L1(Rd). The decay estimates and space-time analyticity are also established for solutions bounded in both space and time variables. The results can be extended to a more general class of equations, including the Navier-Stokes equations.