On the nodal set of solutions to a class of nonlocal parabolic equations

Abstract

We investigate the local properties, including the nodal set and the nodal properties of solutions to the following parabolic problem of Muckenhoupt-Neumann type: equation* cases ∂t u - y-a ∇ ·(ya ∇ u) = 0 & in B1+ × (-1,0) \\ -∂ya u = q(x,t)u & on B1 × \0\ × (-1,0), cases equation* where a∈(-1,1), is a fixed parameter B1+⊂ RN+1 is the upper unit half ball and B1 is the unit ball in RN. Our main motivation comes from its relation with a class of nonlocal parabolic equations involving the fractional power of the heat operator equation* Hsu(x,t) = 1|(-s)| ∫-∞t ∫RN [u(x,t) - u(z,τ)] GN(x-z,t-τ)(t-τ)1+s dzdτ. equation* We characterise the possible blow-ups and we examine the structure of the nodal set of solutions vanishing with a finite order. More precisely, we prove that the nodal set has at least parabolic Hausdorff codimension one in RN×R, and can be written as the union of a locally smooth part and a singular part, which turns out to possess remarkable stratification properties. Moreover, the asymptotic behaviour of general solutions near their nodal points is classified in terms of a class of explicit polynomials of Hermite and Laguerre type, obtained as eigenfunctions to an Ornstein-Uhlenbeck type operator. Our main results are obtained through a fine blow-up analysis which relies on the monotonicity of an Almgren-Poon type quotient and some new Liouville type results for parabolic equations, combined with more classical results including Federer's reduction principle and the parabolic Whitney's extension.