Gaussian bounds, strong ellipticity and uniqueness criteria

Abstract

Let h be a quadratic form with domain W01,2(d) given by \[ h()=Σdi,j=1(∂i,cij\,∂j) \] where cij=cji are real-valued, locally bounded, measurable functions and C=(cij)≥ 0 . If C is strongly elliptic, i.e.\ if there exist λ, μ>0 such that λ\,I≥ C≥ μ \,I>0, then h is closable, the closure determines a positive self-adjoint operator H on L2(d) which generates a submarkovian semigroup S with a positive distributional kernel~K and the kernel satisfies Gaussian upper and lower bounds. Moreover, S is conservative, i.e.\ St= for all t>0. Our aim is to examine converse statements. First we establish that C is strongly elliptic if and only if h is closable, the semigroup S is conservative and K satisfies Gaussian bounds. Secondly, we prove that if the coefficients are such that a Tikhonov growth condition is satisfied then S is conservative. Thus in this case strong ellipticity of C is equivalent to closability of h together with Gaussian bounds on K. Finally we consider coefficients cij∈ W1,∞ loc(d). It follows that h is closable and a growth condition of the T\"acklind type is sufficient to establish the equivalence of strong ellipticity of C and Gaussian bounds on K.