The Klein bottle ratio of two-dimensional ferromagnetic Potts models

Abstract

The weakly first-order nature of the two-dimensional 5-state ferromagnetic Potts model poses challenges for numerical study. Using density-matrix and tensor-network renormalization group methods, we investigate these transitions of the Potts-q model via the Klein bottle ratio g on original and dual lattices. Finite-size scaling of g as a function of transverse system size Ly accurately locates the critical points for q = 4, 5, 6. We further examine the transfer-matrix spectra and entanglement entropy, extracting central charges through toroidal and Klein bottle boundary conditions. For q = 5, the extracted central charge (c ≈ 1.14811) is close to the real part of the theoretical value c5-Potts = 1.1375 0.0211 i predicted by complex conformal field theories. The observed drift in the scaling exponent b effectively distinguishes the continuous transition from the weakly first-order regime. Furthermore, the extrapolated divergence of g confirms the first-order nature of the q=5 Potts model.