On criticality theory for elliptic mixed boundary value problems in divergence form

Abstract

The paper is devoted to the study of positive solutions of a second-order linear elliptic equation in divergence form in a domain D⊂eq Rn that satisfy an oblique boundary condition on a portion of ∂ D. First, we study the degenerate mixed boundary value problem cases Pu=f & in D, \\ Bu = 0 & on ∂ DRob, \\ u=0& on ∂ DDir, cases where D is a bounded Lipschitz domain, ∂ DRob is a relatively open portion of ∂ D, ∂ DDir is a closed set of ∂ D, and B is an oblique (Robin) boundary operator defined on ∂ DRob. In particular, we discuss the unique solvability of the above problem, the existence of a principal eigenvalue, and the existence of a positive minimal Green function. Then we establish a criticality theory for positive weak solutions of the operator (P,B) in a general domain with no boundary condition on ∂ DDir and no growth condition at infinity. The paper generalizes and extends results obtained by Pinchover and Saadon (2002) for classical solutions of such a problem, where stronger regularity assumptions on the coefficients of (P,B), and ∂ DRob.