p-adic limits of renormalized logarithmic Euler characteristics
Abstract
Given a countable residually finite group , we write if is a sequence of normal subgroups of finite index such that any infinite intersection of 's contains only the unit element of . Given a -module we are interested in the multiplicative Euler characteristics \begin{equation} \chi (\Gamma_n , M) = \prod_i |H_i (\Gamma_n , M)|^{(-1)^i} \end{equation} and the limit in the field of -adic numbers \begin{equation} h_p := \lim_{n\to\infty} (\Gamma : \Gamma_n)^{-1} \log_p \chi (\Gamma_n , M) \; . \end{equation} Here is the branch of the -adic logarithm with . Of course, neither expression will exist in general. We isolate conditions on , in particular -adic expansiveness which guarantee that the Euler characteristics are well defined. That notion is a -adic analogue of expansiveness of the dynamical system given by the -action on the compact Pontrjagin dual of . Under further conditions on we also show that the renormalized -adic limit in the second formula exists and equals the -adic -torsion of . The latter is a -adic analogue of the Li--Thom -torsion of a -module which they related to the entropy of the -action on . We view the limit as a version of entropy which values in the -adic numbers and the equality with -adic -torsion as an analogue of the Li--Thom formula in the expansive case. We discuss the case in more detail where our theory is related to Serre's intersection numbers on arithmetic schemes.
Cite
@article{arxiv.1801.02412,
title = {p-adic limits of renormalized logarithmic Euler characteristics},
author = {Christopher Deninger},
journal= {arXiv preprint arXiv:1801.02412},
year = {2018}
}