Set-theoretic solutions of the Pentagon Equation

Abstract

A set-theoretic solution of the Pentagon Equation on a non-empty set S is a map s S2 S2 such that s23s13s12=s12s23, where s12=s×id, s23=id× s and s13=(τ×id)(id× s)(τ×id) are mappings from S3 to itself and τ S2 S2 is the flip map, i.e., τ (x,y) =(y,x). We give a description of all involutive solutions, i.e., s2=id. It is shown that such solutions are determined by a factorization of S as direct product X× A × G and a map σ A(X), where X is a non-empty set and A,G are elementary abelian 2-groups. Isomorphic solutions are determined by the cardinalities of A, G and X, i.e., the map σ is irrelevant. In particular, if S is finite of cardinality 2n(2m+1) for some n,m≥ 0 then, on S, there are precisely n+22 non-isomorphic solutions of the Pentagon Equation.