Poincar\'e theory for compact abelian one-dimensional solenoidal groups

Abstract

This article presents a generalization of the notion of Poincar\'e rotation set to homeomorphisms of the ad\`ele class group A/Q of the rational numbers Q, which is a connected compact abelian group which can be identified with the one-dimensional universal solenoid S, the algebraic universal covering of the circle. The definition is first introduced in general for homeomorphisms of S which are isotopic to a translation, and then specializing in homeomorphisms of S isotopic to the identity, in which case the rotation set is a closed interval contained in the base leaf (the connected component of the identity). If in the latter case the rotation interval reduces to a single element and is irrational ( it is a monothetic generator of S), we show that the homeomorphism is semiconjugate to the translation zz, like in the classical theory of Poincar\'e. This theory is valid for any general compact abelian one dimensional solenoidal group SG, which are Pontryagin duals of dense subgroups G of the rational numbers with the discrete topology. These solenoidal groups are one-dimensional laminations which are locally homeomorphic to the product of a Cantor set by an interval so they behave very much like a ``diffuse'' version of the circle. Our approach differs from others because we use Pontryagin duality of compact abelian groups to define the rotation sets. abstract