A lower bound for polynomial volume growth of automorphisms of zero entropy

Abstract

Let X be a normal projective variety of dimension d, and let f be a zero-entropy automorphism of X. Denote by k the first-degree growth rate of f, so that 1(fn) nk. We prove the sharp lower bound for the polynomial volume growth plov(f) of f: \[ plov(f) d+k(k+2)4, \] equivalently giving a sharp lower bound on the Gelfand--Kirillov dimension of the associated twisted homogeneous coordinate ring. This improves previous lower bounds of Keeler and of Lin--Oguiso--Zhang. In the proof, we introduce the notion of dynamical intersection polynomials and give a new characterization of plov(f) in terms of non-vanishing of intersection numbers. We also establish a gap principle for polynomial volume growth: for every fixed dimension d 4, either plov(f)=d2, or plov(f) d(d-2) + 2 d/4 . This reveals a new rigidity phenomenon for zero-entropy automorphisms. As an application, in dimension 4 we determine all possible values of plov, thereby extending the results of Artin--Van den Bergh for surfaces and Lin--Oguiso--Zhang for threefolds.