Asymptotic Limits and Zeros of Chromatic Polynomials and Ground State Entropy of Potts Antiferromagnets

Abstract

We study the asymptotic limiting function W(G,q) = n ∞P(G,q)1/n, where P(G,q) is the chromatic polynomial for a graph G with n vertices. We first discuss a subtlety in the definition of W(G,q) resulting from the fact that at certain special points qs, the following limits do not commute: n ∞ q qs P(G,q)1/n q qs n ∞ P(G,q)1/n. We then present exact calculations of W(G,q) and determine the corresponding analytic structure in the complex q plane for a number of families of graphs G, including circuits, wheels, biwheels, bipyramids, and (cyclic and twisted) ladders. We study the zeros of the corresponding chromatic polynomials and prove a theorem that for certain families of graphs, all but a finite number of the zeros lie exactly on a unit circle, whose position depends on the family. Using the connection of P(G,q) with the zero-temperature Potts antiferromagnet, we derive a theorem concerning the maximal finite real point of non-analyticity in W(G,q), denoted qc and apply this theorem to deduce that qc(sq)=3 and qc(hc) = (3+5)/2 for the square and honeycomb lattices. Finally, numerical calculations of W(hc,q) and W(sq,q) are presented and compared with series expansions and bounds.

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