Tensor Network Renormalization Study on the Crossover in Classical Heisenberg and RP2 Models in Two Dimensions

Abstract

We study the classical two-dimensional RP2 and Heisenberg models, using the Tensor-Network Renormalization (TNR) method. The determination of the phase diagram of these models has been challenging and controversial, owing to the very large correlation lengths at low temperatures. The finite-size spectrum of the transfer matrix obtained by TNR is useful in identifying the conformal field theory describing a possible critical point. Our results indicate that the ultraviolet fixed point for the Heisenberg model and the ferromagnetic RP2 model in the zero temperature limit corresponds to a conformal field theory with central charge c=2, in agreement with two independent would-be Nambu-Goldstone modes. On the other hand, the ultraviolet fixed point in the zero temperature limit for the antiferromagnetic Lebwohl-Lasher model, which is a variant of the RP2 model, seems to have a larger central charge. This is consistent with c=4 expected from the effective SO(5) symmetry. At T >0, the convergence of the spectrum is not good in both the Heisenberg and ferromagnetic RP2 models. Moreover, there seems no appropriate candidate of conformal field theory matching the spectrum, which shows the effective central charge c 1.9. These suggest that both models have a single disordered phase at finite temperatures, although the ferromagnetic RP2 model exhibits a strong crossover at the temperature where the dissociation of Z2 vortices has been reported.