Infinite sequences via Lie algebra actions for oligomorphic groups

Abstract

Many integer sequences arise as numbers of G-orbits on Xn as n varies, for a permutation group G⊂eq Sym(X). For finite X, Stanley proved that these finite sequences increase towards the middle using an action of the Lie algebra sl2(C). For infinite sets X, and hence infinite sequences, Cameron provided an argument for monotonicity by identifying orbits with a vector space basis of the orbit algebra HG,X, and proving injectivity of a certain operator HG,X HG,X+1. In this paper we generalize Stanley's approach to oligomorphic groups, and in particular extend Cameron's operator to a full sl2(C)-action on HG,X. As intermediate step, we define for every oligomorphic permutation group G⊂eq Sym(X) the X-th tensor power (kr) X, generalizing work of Entova-Aizenbud. We show that this space carries natural commuting actions of G and the Lie algebra glr(k), the latter depending on a Harman-Snowden measure μ on G. We then show that HG,X⊂eq (C2) X has an ascending filtration by sl2(C)-Verma modules. We explain how our approach applies to Fibonacci numbers, Tribonacci numbers, etc. by constructing measures on products with (Q,<).