Coarse-grained ellipticity and De Giorgi-Nash-Moser theory

Abstract

We prove local boundedness and a Harnack inequality for nonnegative weak solutions of the equation -∇·(a(x)∇ u)=0 under a coarse-grained ellipticity assumption on the symmetric coefficient field a. Coarse-grained ellipticity is a scale-dependent condition, defined for fields with only a,a-1∈ L1, in terms of families of effective diffusion matrices on triadic cubes of all sizes, and our estimates depend quantitatively on a corresponding coarse-grained ellipticity ratio. We show that coarse-grained ellipticity can be enforced by purely negative Sobolev regularity hypotheses: if a∈ L1 W-s,p(U) and a-1∈ L1 W-t,q(U) for exponents p,q∈[1,∞] and s,t∈[0,1) satisfying s<1-1p, t<1-1q and \[ s+t2 + d2(1p+1q) < 1, \] then a is coarse-grained elliptic in U and every nonnegative solution satisfies a quantitative unit-scale Harnack inequality. In particular, when s=t=0 we recover Trudinger's classical result under the integrability condition a∈ Lp, a-1∈ Lq with 1p+1q<2d, and we obtain the sharp scaling of the Harnack constant in terms of \|a\|Lp and \|a-1\|Lq. More importantly, our criteria apply to new classes of degenerate and singular coefficient fields for which a,a-1 L1+δ for all δ>0, including examples generated by singular fractal measures and Gaussian multiplicative chaos, beyond the reach of previous approaches based solely on integrability assumptions.