Global Calder\`on & Zygmund theory for nonlinear parabolic systems

Abstract

We establish a global Calder\'on & Zygmund theory for solutions of a huge class of nonlinear parabolic systems whose model is the inhomogeneous parabolic p-Laplacian system equation* \arraycc ∂t u - (|Du|p-2Du) = (|F|p-2F) &in T:=×(0,T) \\[5pt] u=g &on ∂×(0,T) ×\0\ array. equation* with given functions F and g. Our main result states that the spatial gradient of the solution is as integrable as the data F and g up to the lateral boundary of T, i.e. equation* F,Dg∈ Lq(T),\ \ ∂t g∈ Lq(n+2)p(n+2)-n(T) ⇒ Du∈ Lq(×(δ,T)) equation* for any q>p and δ∈(0,T), together with quantitative estimates. This result is proved in a much more general setting, i.e. for asymptotically regular parabolic systems.