Spanning forests and the q-state Potts model in the limit q 0

Abstract

We study the q-state Potts model with nearest-neighbor coupling v=eβ J-1 in the limit q,v 0 with the ratio w = v/q held fixed. Combinatorially, this limit gives rise to the generating polynomial of spanning forests; physically, it provides information about the Potts-model phase diagram in the neighborhood of (q,v) = (0,0). We have studied this model on the square and triangular lattices, using a transfer-matrix approach at both real and complex values of w. For both lattices, we have computed the symbolic transfer matrices for cylindrical strips of widths 2 L 10, as well as the limiting curves of partition-function zeros in the complex w-plane. For real w, we find two distinct phases separated by a transition point w=w0, where w0 = -1/4 (resp. w0 = -0.1753 0.0002) for the square (resp. triangular) lattice. For w > w0 we find a non-critical disordered phase, while for w < w0 our results are compatible with a massless Berker-Kadanoff phase with conformal charge c = -2 and leading thermal scaling dimension xT,1 = 2 (marginal operator). At w = w0 we find a "first-order critical point": the first derivative of the free energy is discontinuous at w0, while the correlation length diverges as w w0 (and is infinite at w = w0). The critical behavior at w = w0 seems to be the same for both lattices and it differs from that of the Berker-Kadanoff phase: our results suggest that the conformal charge is c = -1, the leading thermal scaling dimension is xT,1 = 0, and the critical exponents are = 1/d = 1/2 and α = 1.

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