Mixed-Parabolicity and Mixed-Liouville Property for Products of Riemannian Manifolds

Abstract

Let p1,p2∈(1,∞) and M=M1× M2 be the product of two geodesically complete Riemannian manifolds. In this paper, the authors first develop an anisotropic potential-theoretic framework adapted to the Green operator GM and the mixed-norm Lebesgue space Lp2(Lp1)(M), and then demonstrate that the classical equivalence among parabolicity, Green function integrability, and Liouville property persists in this genuinely anisotropic setting. More precisely, the authors establish the following equivalence: M is Lp2(Lp1)-parabolic if and only if the Green function GM(x;\,·\,) fails to belong to Lp2'(Lp1')(M B(x,\,r)), which is in turn equivalent to the Lp2'(Lp1')-Liouville property, where pi' denotes the conjugate exponent of pi. Under a weak radial Harnack-type inequality -- in particular, under Li--Yau heat kernel estimates, and hence for products of manifolds with nonnegative Ricci curvature -- these conditions are further equivalent to the divergence of the nonlinear mixed-potential Gp1,p2(f) for every nonzero nonnegative f∈ Cc∞(M). A key feature of this anisotropic theory is its sensitivity to the geometry of each factor \(Mi\), rather than merely to that of the total manifold \(M\). In contrast to the isotropic case, where parabolicity and the classical Liouville property holds on \(Rn\) precisely when \(n 2\), the anisotropic setting exhibits a refined threshold: the \(Lp2(Lp1)\)-parabolicity and the \(Lp2'(Lp1')\)-Liouville property holds on \(Rn1 × Rn2\) if and only if Deff := n1p1 + n2p2 2. This effective dimension Deff captures the anisotropic interplay between the exponents \(p1, p2\) and the geometries of \(M1, M2\).