Lower bounds for multivariate independence polynomials and their generalisations

Abstract

In statistical physics, the multivariate hard-core model describes a system of particles, each of which receives its own fugacity. In graph-theoretic language, the partition function of the model translates to the multivariate independence polynomial, i.e., the multiaffine generalisation of the independence polynomial, defined by ZG(λ1,…,λn) := ΣI∈I(G) Πv∈ Iλv, where I(G) denotes the set of all independent sets in a graph G on [n]:=\1,2,…,n\. We prove that for every simple graph G on [n] and λ1,…,λn≥ 0, \[ ZG(λ1,…,λn) ≥ Πi=1n (1+(di+1)λi)1/(di+1), \] where d1,…,dn is the degree sequence of G. This generalises a result of Sah, Sawhney, Stoner, and Zhao, who proved the univariate case λ1=…=λn=λ. We further conjecture that our inequality should generalise to other antiferromagnetic models and give some evidence in support of it. In particular, for λi,μi≥ 0, 1≤ i≤ n, we obtain a stronger inequality \[ ΣI,J∈ I(G) \\ I J= Πv∈ IλvΠu∈ Jμu ≥ Πi=1n (1+(di+1)(λi+μi)+di(di+1)λiμi)1/(di+1), \] which proves our conjecture for a multiaffine generalisation of the semiproper colouring partition function with two proper colours. Our key technical steps for both theorems are obtained by using a custom mathematical research agent built on top of Gemini Deep Think, which can be seen as a benchmark demonstrating that the current state-of-the-art language models can, in part, assist with mathematical research.