Roots in the mapping class groups
Abstract
The purpose of this paper is the study of the roots in the mapping class groups. Let be a compact oriented surface, possibly with boundary, let be a finite set of punctures in the interior of , and let (, ) denote the mapping class group of (, ). We prove that, if is of genus 0, then each f ∈ () has at most one m-root for all m 1. We prove that, if is of genus 1 and has non-empty boundary, then each f ∈ () has at most one m-root up to conjugation for all m 1. We prove that, however, if is of genus 2, then there exist f,g ∈ (, ) such that f2=g2, f is not conjugate to g, and none of the conjugates of f commutes with g. Afterwards, we focus our study on the roots of the pseudo-Anosov elements. We prove that, if ∂ ≠ , then each pseudo-Anosov element f ∈ (, ) has at most one m-root for all m 1. We prove that, however, if ∂ = and the genus of is 2, then there exist two pseudo-Anosov elements f,g ∈ () (explicitely constructed) such that fm=gm for some m 2, f is not conjugate to g, and none of the conjugates of f commutes with g. Furthermore, if the genus of is 0 ( 4), then we can take m=2. Finally, we show that, if is a pure subgroup of (, ) and f ∈ , then f has at most one m-root in for all m 1. Note that there are finite index pure subgroups in (, ).
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