A Bond weighted tensor renormalization group study of the q-state ferromagnetic Potts models on the square lattice
Abstract
It is known rigorously that the phase transition of the q-state ferromagnetic Potts model on the square lattice is second order for q=4. Despite this fact, some observables of the q=4 model show features of a first-order phase transition. For example, negative peak appears for the quantity of Binder ratio Q2 of this model. Such a non-monotonic behavior of Q2 is typically a consequence of phase coexistence, hence is served as a signal of a first-order phase transition. In particular, the negative peak should diverge with linear system size L squared. Since the mentioned divergence phenomenon is not observed for the 4-state Potts model, the scenario of a first-order phase transition for this model is ruled out. Interestingly, a recent large scale Monte Carlo investigation of the 4-state Potts model observes that the two-peak structure of the energy density distribution becomes more noticeable when L increases. This finding indicates the signal of coexistence of phases is getting stronger with L. Due to these unusual critical behaviors, here we study the energy density E and the specific heat Cv of the 4-state Potts model on the square lattice using the technique of bond weighted tensor renormalization group (BWTRG). For a comparison purpose, q=2 and q=5 ferromagnetic Potts models on the square lattice are investigated using the same method as well. Remarkably, our results do imply there may be a small energy gap for q=4 model. While the appearance of the mentioned small energy gap can be explained plausibly and it will disappear with a more sophisticated investigation, our finding suggests that whether a message of a first-order phase transition is genuine or is an artificial effect requires further and detailed investigations.
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