Gauged permutation invariant tensor quantum mechanics, least common multiples and the inclusion-exclusion principle

Abstract

We derive the canonical ensemble partition functions for gauged permutation invariant tensor quantum harmonic oscillator thermodynamics, finding surprisingly simple expressions with number-theoretic characteristics. These systems have a gauged symmetry of SN, the symmetric group of all permutations of a set of N objects. The symmetric group acts on tensor variables i1, ·s , is , where the s indices each range over \ 1, 2, ·s , N \ and have the standard SN action of permutations. The result is a sum over partitions of N and the summand is a product admitting simple expressions, which depend on the least common multiples (LCMs) of subsets of the parts of the partition. The inclusion-exclusion principle of combinatorics plays a central role in the derivation of these expressions. The behaviour of these partition functions under inversion of the Boltzmann factor x = e - β is governed by universal sequences associated with invariants of symmetric groups and alternating groups. The partition functions allow the development of a high temperature expansion analogous to the s=2 matrix case. The calculation of an s-dependent breakdown point leads to a critical Boltzmann factor xc = N sN s-1 as the leading large N approximation.