Diagnosing SO(5) Symmetry and First-Order Transition in the J-Q3 Model via Entanglement Entropy

Abstract

We study the scaling behavior of the R\'enyi entanglement entropy with smooth boundaries at the phase transition point of the two-dimensional J-Q3 model. Using the recently developed scaling formula [Deng et al., Phys. Rev. B 108, 125144 (2023)], we find a subleading logarithmic term with a coefficient showing that the number of Goldstone modes is four, indicating the existence of the spontaneous symmetry breaking from an emergent SO(5) to O(4) in the thermodynamic limit, but restored in a finite size. This result shows that the believed deconfined quantum critical point of the J-Q3 model is a weak first-order transition point. Our work provides a new way to distinguish a state with spontaneously broken continuous symmetry from a critical state. The method is particularly useful in identifying weak first-order phase transitions, which are hard to determine using conventional methods.