Monte Carlo Determination of the Low-Energy Constants of a Spin 1/2 Heisenberg Model with Spatial Anisotropy

Abstract

Motivated by the possible mechanism for the pinning of the electronic liquid crystal direction in YBCO as proposed in Pardini08, we use the first principles Monte Carlo method to study the spin 1/2 Heisenberg model with antiferromagnetic couplings J1 and J2 on the square lattice. The corresponding low-energy constants, namely the spin stiffness s, the staggered magnetization density Ms, the spin wave velocity c, as well as the ground state energy density e0 are determined by fitting the Monte Carlo data to the predictions of magnon chiral perturbation theory. In particular, the spin stiffnesses s1 and s2 are investigated as a function of the ratio J2/J1 of the couplings. Although we find a good agreement between our results with those obtained by the series expansion method in the weakly anisotropic regime, for strong anisotropy we observe discrepancies.