Unconventional U(1) to $\mathbf{Z_q}$ cross-over in quantum and classical ${\bf q}$-state clock models

Abstract: We consider two-dimensional q-state quantum clock models with quantum fluctuations connecting states with all-to-all clock transitions with different choices for the matrix elements. We study the quantum phase transitions in these models using quantum Monte Carlo simulations and finite-size scaling, with the aim of characterizing the cross-over from emergent U(1) symmetry at the transition (for q ≥ 4) to Zq symmetry of the ordered state. We also study classical three-dimensional clock models with spatial aniso… Show more

“…This causes indeed the appearance of a crossover between a U(1) symmetric and a Z N symmetric regime in the ordered phase. This analysis has been numerically well-verified for the classical 3D model (see, for example, [77,79]), and it has been recently confirmed also for the quantum 2D case [80], thus leading to the conclusion that no gapless phase exists for the clock limit g → 0 and the dual pure LGT λ → 0 [77].…”

“…In three dimensions, it is indeed known that the classical clock model does not display an extended gapless phase due to the P background terms being "dangerously irrelevant" perturbations and the system displays only a single phase transition in the 3D XY model universality class. This is due to the fact that the irrelevant P operators become relevant when approaching the U (1) symmetric gapless Nambu-Goldstone fixed point [78], thus causing a second step in the RG flow towards the ordered ferromagnetic phase of the clock model (see the phase diagrams evaluated in [79,80]). As a consequence, the system is characterized by two different length scales ξ < ξ , both diverging at the critical point, which are associated with the onset of U (1) and Z N symmetric features respectively.…”

$\mathbb{Z}_N$ lattice gauge theory in a ladder geometry

“…This causes indeed the appearance of a crossover between a U(1) symmetric and a Z N symmetric regime in the ordered phase. This analysis has been numerically well-verified for the classical 3D model (see, for example, [77,79]), and it has been recently confirmed also for the quantum 2D case [80], thus leading to the conclusion that no gapless phase exists for the clock limit g → 0 and the dual pure LGT λ → 0 [77].…”

“…In three dimensions, it is indeed known that the classical clock model does not display an extended gapless phase due to the P background terms being "dangerously irrelevant" perturbations and the system displays only a single phase transition in the 3D XY model universality class. This is due to the fact that the irrelevant P operators become relevant when approaching the U (1) symmetric gapless Nambu-Goldstone fixed point [78], thus causing a second step in the RG flow towards the ordered ferromagnetic phase of the clock model (see the phase diagrams evaluated in [79,80]). As a consequence, the system is characterized by two different length scales ξ < ξ , both diverging at the critical point, which are associated with the onset of U (1) and Z N symmetric features respectively.…”

$\mathbb{Z}_N$ lattice gauge theory in a ladder geometry

“…For larger values of q, we expect a continuous transition. It belongs to the Ising universality class for q = 4 [64], and to the 3D XY universality class for q ≥ 5 [64][65][66].…”

Higher-charge three-dimensional compact lattice Abelian-Higgs models