Exotic Quantum Criticality in One-Dimensional Coupled Dipolar Bosons Tubes

TL;DR

This paper explores a novel quantum phase transition in one-dimensional coupled dipolar bosonic tubes, revealing exotic critical behavior described by Z_N parafermionic conformal field theories with potential applications in ultracold quantum gases.

Contribution

It introduces a new understanding of quantum criticality involving Z_N parafermions in coupled dipolar bosonic systems using bosonization and conformal field theory.

Findings

Identification of a U(1) x Z_N critical point with fractional central charge

Main properties of the critical point in double-tube systems with c=3/2

Connection between multi-tube systems and Z_N chiral Potts models

Abstract

The competition between intertube hopping processes and density-density interactions is investigated in one-dimensional quantum dipolar bosons systems of N coupled tubes at zero temperature. Using a phenomenological bosonization approach, we show that the resulting competition leads to an exotic quantum phase transition described by a U(1) x Z_N conformal field theory with a fractional central charge. The emerging Z_N parafermionic critical degrees of freedom are highly nontrivial in terms of the original atoms or polar molecules of the model. We further determine the main physical properties of the quantum critical point in a double-tube system which has central charge c=3/2. In triple-tube systems, we show that the competition between the two antagonistic processes is related to the physics of the two-dimensional Z_3 chiral Potts model. This work opens the possibility to study the exotic properties of the Z_N parafermions in the context of ultracold quantum Bose gases.