The Lipschitz Liouville Property, Affine Rigidity, and Coarse Harmonic Coordinates on Groups of Polynomial Growth

Abstract

We develop a quantitative theory of Lipschitz harmonic functions (LHF) on finitely generated groups, with emphasis on the Lipschitz Liouville property, affine rigidity, and quasi-isometric invariance for groups of polynomial growth. On finitely generated nilpotent groups we prove an affine rigidity theorem: for any adapted, smooth, Abelian-centered probability measure μ, every Lipschitz μ-harmonic function is affine, f(x)=c+φ([x]). For any finite generating set S this yields a canonical isometric identification LHF(G,μ)/C Hom(Gab,C), \|∇S f\|∞=s∈ S|φ([s])|, independent of the choice of centered measure. In addition, we prove an identification of HF1 with LHF on polynomial growth groups for adapted, smooth, Abelian-centered measures. Next, for any finite-index subgroup H G and adapted smooth μ we prove a quantitative induction-restriction principle: restriction along H and an explicit averaging operator give a linear isomorphism LHF(G,μ)(H,μH), where μH is the hitting measure, with two-sided control of the Lipschitz seminorms. For groups of polynomial growth equipped with SAS measures we then show that LHF is a quasi-isometry invariant as a seminormed affine space, via choice-dependent Shalom--Sauer transport on virtual first cohomology. Separately, for quasi-isometries with bounded Abelian defect, we construct coarse harmonic coordinates that straighten them up to bounded error. Finally, within the Lyons-Sullivan/Ballmann-Polymerakis discretization framework, we prove a quantitative discrete-to-continuous extension theorem: Lipschitz harmonic data on an orbit extend to globally Lipschitz L-harmonic functions on the ambient manifold, with gradient bounds controlled by the background geometry.