Green geometry, Martin boundary and random walk asymptotics on groups
Abstract
We identify a single computationally checkable analytic quantity interlacing Martin boundary collapse, Green geometry, and linear escape for transient random walks on finitely generated groups: the Green-variation functional \[ (S;a,b):=x∈∂ S|G(a,x)-G(b,x)|G(a,x). \] We prove that 0 along exhaustions characterises the strong Liouville property (under mild, verifiable hypotheses on the ``strong Liouville ⇒ 0'' direction), turning boundary oscillation estimates for Green kernels into potential-theoretic rigidity. We then give two general criteria for -vanishing. The first one derives quantitative bounds on from coarse heat-kernel envelopes at an intrinsic scale together with a Tauberian comparability, covering Gaussian/sub-Gaussian and stable-like regimes; and the second one is purely elliptic: an ``elliptic H\"older exhaustion'' criterion. Conversely, on groups of exponential growth, fails to decay along balls already under stretched-exponential on-diagonal upper bounds, yielding a quantitative obstruction to strong Liouville. As consequences, trivial Martin boundary forces linear-scale collapse of Green geometry (dG(e,x)=o(|x|)) and vanishing Green speed (in probability), without any entropy hypothesis. On the non-Liouville side we prove an abundance principle: the existence of a single minimal positive harmonic function at a prescribed growth scale forces infinitely many. Finally, we clarify the role of moment assumptions in speed theory: any linear-speed law of large numbers on a set of positive probability forces E|X1|<∞, while on torsion-free nilpotent groups one can have E|X1|=∞ yet |Xn|/n0 in probability.
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