Non-divergence form parabolic equations associated with non-commuting vector fields: Boundary behavior of nonnegative solutions

Abstract

In a cylinder T=× (0,T)⊂ n+1+ we study the boundary behavior of nonnegative solutions of second order parabolic equations of the form \[ Hu =Σi,j=1maij(x,t) XiXju - tu = 0, \ (x,t)∈n+1+, \] where X=\X1,...,Xm\ is a system of C∞ vector fields in satisfying H\"ormander's finite rank condition frc, and is a non-tangentially accessible domain with respect to the Carnot-Carath\'eodory distance d induced by X. Concerning the matrix-valued function A=\aij\, we assume that it be real, symmetric and uniformly positive definite. Furthermore, we suppose that its entries aij be H\"older continuous with respect to the parabolic distance associated with d. Our main results are: 1) a backward Harnack inequality for nonnegative solutions vanishing on the lateral boundary (Theorem T:back); 2) the H\"older continuity up to the boundary of the quotient of two nonnegative solutions which vanish continuously on a portion of the lateral boundary (Theorem T:quotients); 3) the doubling property for the parabolic measure associated with the operator H (Theorem T:doubling). These results generalize to the subelliptic setting of the present paper, those in Lipschitz cylinders by Fabes, Safonov and Yuan in [FSY] and [SY]. With one proviso: in those papers the authors assume that the coefficients aij be only bounded and measurable, whereas we assume H\"older continuity with respect to the intrinsic parabolic distance.