Correction-to-scaling exponent for percolation and the Fortuin--Kasteleyn Potts model in two dimensions

Abstract

The number ns of clusters (per site) of size s, a central quantity in percolation theory, displays at criticality an algebraic scaling behavior of the form ns s-τ\, A\, (1+B s-). For the Fortuin--Kasteleyn representation of the Q-state Potts model in two dimensions, the Fisher exponent τ is known as a function of the real parameter 0 Q4, and, for bond percolation (the Q→ 1 limit), the correction-to-scaling exponent is derived as =72/91. We theoretically derive the exact formula for the correction-to-scaling exponent =8/[(2g+1)(2g+3)] as a function of the Coulomb-gas coupling strength g, which is related to Q by Q=2+2(2 π g). Using an efficient Monte Carlo cluster algorithm, we study the O(n) loop model on the hexagonal lattice, which is in the same universality class as the Q=n2 Potts model, and has significantly suppressed finite-size corrections and critical slowing-down. The predictions of the above formula include the exact value for percolation as a special case and agree well with the numerical estimates of for both the critical and tricritical branches of the Potts model.

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