Geometric properties of the Fortuin-Kasteleyn representation of the Ising model

Abstract

We present a Monte Carlo study of the Fortuin-Kasteleyn (FK) clusters of the Ising model on the square (2D) and simple-cubic (3D) lattices. The wrapping probability, a dimensionless quantity characterizing the topology of the FK clusters on a torus, is found to suffer from smaller finite-size corrections than the well-known Binder ratio, and yields a high-precision critical coupling as Kc(3 D)=0.221\,654\,631(8). We then study geometric properties of the FK clusters at criticality. It is demonstrated that the distribution of the critical largest-cluster size C1 follows a single-variable function as P(C1,L) dC1= P(x) dx with x C1/Ld F (L is the linear size), and that the fractal dimension d F is identical to the magnetic exponent. An interesting bimodal feature is observed in distribution P(x) in 3D, and attributed to the different approaching behaviors for K Kc+0. For a critical FK configuration, the cluster number per site n(s,L) of size s is confirmed to obey the standard scaling form n(s,L) s-τ n(s/Ld F), with hyper-scaling relation τ=1+d/d F and the spatial dimension d. To further characterize the compactness of the FK clusters, we measure their graph distances and determine the shortest-path exponents as d min(3 D)=1.259\,4(2) and d min(2 D)=1.094\,0(3). Further, by excluding all the bridges from the occupied bonds, we obtain bridge-free configurations and determine the backbone exponents as d B(3 D)=2.167\,3(15) and d B(2 D)=1.732\,1(4). The estimates of the universal wrapping probabilities for the 3D Ising model and of the geometric critical exponents d min and d B either improve over the existing results or have not been reported yet.