Non-divergence form parabolic equations associated with non-commuting vector fields: Boundary behavior of nonnegative solutions (1008.5082v1)

Abstract: In a cylinder $\Omega_T=\Omega\times (0,T)\subset \R^{n+1}_+$ we study the boundary behavior of nonnegative solutions of second order parabolic equations of the form [ Hu =\sum_{i,j=1}^ma_{ij}(x,t) X_iX_ju - \p_tu = 0, \ (x,t)\in\R^{n+1}_+, ] where $X={X_1,...,X_m}$ is a system of $C^\infty$ vector fields in $\Rn$ satisfying H\"ormander's finite rank condition \eqref{frc}, and $\Omega$ is a non-tangentially accessible domain with respect to the Carnot-Carath\'eodory distance $d$ induced by $X$. Concerning the matrix-valued function $A={a_{ij}}$, we assume that it be real, symmetric and uniformly positive definite. Furthermore, we suppose that its entries $a_{ij}$ 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 \ref{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 \ref{T:quotients}); 3) the doubling property for the parabolic measure associated with the operator $H$ (Theorem \ref{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 $a_{ij}$ be only bounded and measurable, whereas we assume H\"older continuity with respect to the intrinsic parabolic distance.