Two-dimensional J1-J2 clock model: Enhanced symmetries, emergent orders, and Landau-incompatible transitions

Abstract

We present a comprehensive study on the frustrated J1-J2 classical q-state clock model with even q>4 on a two-dimensional square lattice, revealing a rich ensemble of phases driven by competing interactions. In the unfrustrated regime (J1>2J2), the model reproduces the standard clock model phenomenology: a low-temperature Zq-broken ferromagnet, an intermediate XY-like critical quasi-long-range-ordered (QLRO) phase with emergent U(1) symmetry, and a high-temperature paramagnet. For J1<2J2, frustration stabilizes five distinct regimes: the disordered paramagnet, a stripe-ordered phase breaking Zq×Z2 symmetry, two Z2-broken nematic phases (one with and one without QLRO), and an exotic stripe phase with emergent discrete Zq spin degrees of freedom prohibited in the microscopic Hamiltonian. Remarkably, this seemingly forbidden Zq order emerges via a relevant operator in the infrared long-wavelength limit, rather than from an irrelevant perturbation, highlighting a non-standard route to emergence. Using large-scale corner transfer matrix renormalization group calculations, complemented by classical Monte Carlo simulations, we map the complete phase diagram and identify Berezinskii-Kosterlitz-Thouless, Ising, first-order, and unconventional Landau-incompatible transitions between different phases. Finally, we propose an effective field-theoretic framework that encompasses these emergent orders and their interwoven transitions.