The Phase Transition of the Spin-1/2 Heisenberg Model with a Spatially Staggered Anisotropy on the Square Lattice
arXiv:0911.0653
Abstract
Puzzled by the indication of a new critical theory for the spin-1/2 Heisenberg model with a spatially staggered anisotropy on the square lattice as suggested in \cite{Wenzel08}, we re-investigate the phase transition of this model induced by dimerization. We focus on studying the finite-size scaling of the observables $Ï_{s1} L$ and $Ï_{s2} L$, where $L$ stands for the spatial box sizes used in the simulations and $Ï_{si}$ with $i \in \{1,2\}$ is the spin-stiffness in $i$-direction. We find by performing finite-size scaling using the observable $Ï_{s2} L$, which corresponds to the spatial direction with a fixed antiferromagnetic coupling, one would suffer a much less severe correction compared to that of using $Ï_{s1} L$. Therefore $Ï_{s2} L$ is a better quantity than $Ï_{s1} L$ for finite-size scaling analysis concerning the limitation for the availability of large volumes data in our study. Remarkably, by employing the method of fixing the aspect-ratio of spatial winding numbers squared in the simulations, even from $Ï_{s1} L$ which receives the most serious correction among the observables considered in this study, we arrive at a value for the critical exponent $ν$ which is consistent with the expected O(3) value by using only up to $L = 64$ data points.
4 pages, 7 figures