II Critical finite-size scaling functions

[69.1.1.1] We consider the two-dimensional Ising model on a square lattice of side length $L$ . The $N=L^{2}$ spins $\sigma _{i}=\pm 1$ interact according to the Hamiltonian $\mathcal{H}=-J\sum _{{(i,j)}}\sigma _{i}\sigma _{j}-H\sum _{{i=1}}^{N}\sigma _{i}$ where $J>0$ is the ferromagnetic coupling strength and $H$ is an external field. [69.1.1.2] The first summation $\sum _{{(i,j)}}$ runs over all nearest neighbour pairs on the lattice. [69.1.1.3] The order parameter is the magnetization per spin

$m=\frac{1}{N}\sum _{{i=1}}^{{N}}\sigma _{i}$

(1)

whose value fulfills $-1\leq m\leq 1$ . [69.1.1.4] In the following we set $J=1$ and also the Boltzmann constant to unity. [69.1.1.5] We denote the temperature by $T$ , and write $h=H/(k_{B}T)$ for the magnetic field.

In this paper we focus on the probability density $p(m)$ of the order parameter defined as

$p(m)=\frac{\sum _{{\{\sigma\}}}\delta\left(\sum _{{i=1}}^{{N}}\sigma _{i},Nm\right)\exp(-\beta\mathcal{H})}{\sum _{{\{\sigma\}}}\exp(-\beta\mathcal{H})}$

(2)

where $\beta=1/(k_{B}T)$ , $\delta(i,j)=\delta _{{ij}}$ is a Kronecker $\delta$ , and where $m$ is such that $|Nm/2|$ is an integer not larger than $N/2$ . [69.1.1.6] The probability density $p(m)$ depends parametrically on temperature $T$ , field $h$ and system size $N=L^{2}$ ,

$p(m)=p(m;T,h,L).$

(3)

It is also called order parameter distribution. [69.1.1.7] In the following we limit ourselves to the case $h=0$ , and hence $p(m)=p(m;T,L)$ . [69.1.1.8] The critical order parameter distribution is obtained in the limit $L\to\infty$ and $T\to T_{c}$ where $T_{c}=2/{\rm arsinh}(1)\approx 2.2691853...$ is the critical temperature. [69.1.1.9] There are different ways of taking this limit (see [23] for an overview). [69.1.1.10] Traditionally this limit is understood as the finite-size scaling limit defined by

$L\to\infty,\ T\to T_{c}\ \ \quad\text{such that}\ \ \quad L/\xi\approx 1<\infty$

(4)

where $\xi=\xi(T)$ is the temperature dependent spin-spin-correlation length for the infinite system. [69.1.1.11] Note that in an infinite system $\xi(T)\to\infty$ as $T\to T_{c}$ . [69.1.1.12] A second way to take the limit is the finite ensemble scaling limit defined through [23]

$L\to\infty,\ T\to T_{c}\ \ \quad\text{ such that }\ \ \quad L/\xi\to\infty.$

(5)

[69.2.0.1] All other possibilities for taking the limits are discussed in [23]. [69.2.0.2] It is often postulated that $\xi$ fulfills the finite size scaling hypothesis

$\xi(t,L)=L\widetilde{\xi}(tL^{{1/\nu}})$

(6)

in the finite-size scaling limit. [69.2.0.3] Here $t=(T-T_{c})/T_{c}$ is the reduced temperature, $\widetilde{\xi}(x)$ is a universal scaling function and $\nu$ is the correlation length exponent. For the two-dimensional Ising model $\nu=1$ .

[69.2.1.1] The traditional finite-size scaling hypothesis [13, 24] for the critical order parameter distribution assumes that

$p(m;T=T_{c},L)=p(m;L)=L^{{\beta/\nu}}\widetilde{p}(mL^{{\beta/\nu}})$

(7)

where $\widetilde{p}(x)$ is the universal scaling function of the order parameter distribution and $\beta$ is the order parameter exponent. [69.2.1.2] For the two-dimensional Ising model [25]

$\beta=\frac{1}{8}.$

(8)

Our scaling variable is then

$x=mL^{{1/8}}.$

(9)

Using the scaling assumption (7) one obtains the absolute moments of the critical order parameter distribution

$\langle|m|^{k}\rangle(L)=\int|m|^{k}p(m;L){\rm d}m=L^{{-k\beta/\nu}}\widetilde{m}_{k}$

(10)

where

$\widetilde{m}_{k}=\int|x|^{k}\widetilde{p}(x){\rm d}x.$

(11)

[69.2.1.3] From these one calculates the so called renormalized coupling constant $g=\widetilde{m}_{4}/\widetilde{m}_{2}^{2}$ or the Binder cumulant

$U_{L}=1-\frac{\widetilde{m}_{4}}{3\widetilde{m}_{2}^{2}}$

(12)

which are often used in studies of critical behaviour because they are independent of $L$ at criticality, if all the assumptions are valid.

Authors:	R. Hilfer, B. Biswal, H.G. Mattutis, W. Janke
originally published in:	Physical Review E68, 046123 (2003)
originally submitted:	January 28th, 2003