Proof of a conjecture of Green and Liebeck on codes in symmetric groups
Abstract
Let A and B be subsets of a finite group G and r a positive integer. If for every g∈ G, there are precisely r pairs (a,b)∈ A× B such that g=ab, then B is called a code in G with respect to A and we write r G=A·B. If in addition B is a subgroup of G, then we say that B is a subgroup code in G. In this paper we resolve a conjecture by Green and Liebeck [Conjecture 2.3]Green20 on certain subgroup codes in the symmetric group Sn. Let n>2k and let j be such that 2j≤slant k<2j+1. Suppose that X is a conjugacy class in Sn containing x, and Yk is the subgroup Sk× Sn-k of Sn, where the factor Sk permutes the subset \1,…,k\ and the factor Sn-k permutes the subset \k+1,…,n\. We prove that r Sn=X·Yk for some positive integer r if and only if the cycle type of x has exactly one cycle of length 2i for 0≤slant i≤slant j and all other cycles have length at least k+1. We also propose several problems concerning the existence of certain subgroup codes in a finite group G with respect to a conjugation-closed subset in G.
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