Solving the puzzle of an unconventional phase transition for a 2d dimerized quantum Heisenberg model

Abstract

Motivated 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 Wenzel08, we re-investigate the phase transition of this model induced by dimerization using first principle Monte Carlo simulations. We focus on studying the finite-size scaling of s1 2L and s2 2L, where L stands for the spatial box size used in the simulations and si with i ∈ \1,2\ is the spin-stiffness in the i-direction. Remarkably, while we do observe a large correction to scaling for the observable s12L as proposed in Fritz11, the data for s22L exhibit a good scaling behavior without any indication of a large correction. As a consequence, we are able to obtain a numerical value for the critical exponent which is consistent with the known O(3) result with moderate computational effort. Specifically, the numerical value of we determine by fitting the data points of s22L to their expected scaling form is given by =0.7120(16), which agrees quantitatively with the most accurate known Monte Carlo O(3) result = 0.7112(5). Finally, while we can also obtain a result of from the observable second Binder ratio Q2 which is consistent with =0.7112(5), the uncertainty of calculated from Q2 is more than twice as large as that of determined from s22L.