Equilibrium and dynamical quantum phase transitions in dipolar atomic Josephson junctions
Abstract
An atomic Josephson junction realized with dipolar bosons in a double-well potential can be described by an extended Bose-Hubbard model in which dipolar interactions generate an effective on-site interaction and nearest-neighbor pair tunneling. Using mean-field theory and exact diagonalization, we investigate how this correlated process affects zero-temperature equilibrium and dynamical properties of the system. In equilibrium, we show that pair tunneling induces ground-state parity modulations and significantly reshapes the phase diagram, producing qualitative changes in the quantum phase transitions toward NOON and phase-NOON states, as well as quantitative shifts of the critical points. Out of equilibrium, we demonstrate that it modifies the conditions for macroscopic quantum self-trapping, and assess its impact by comparing mean-field and fully quantum evolution, including the emergence of dynamical quantum phase transitions.
Cite
@article{arxiv.2602.20322,
title = {Equilibrium and dynamical quantum phase transitions in dipolar atomic Josephson junctions},
author = {Cesare Vianello and Giovanni Mazzarella and Luca Salasnich},
journal= {arXiv preprint arXiv:2602.20322},
year = {2026}
}
Comments
18 pages, 9 figures