English

Enhancing supercurrent-based inertial sensing via interactions in atomtronic angular accelerometers

Quantum Gases 2026-05-05 v1 Quantum Physics

Abstract

We theoretically investigate supercurrents of ultracold atoms in angularly ac-shaken ring lattices subjected to external rotation. Our results demonstrate how these supercurrents can be harnessed for the development of high-precision atomtronic angular accelerometers. Using both analytical and numerical approaches within the Bose-Hubbard model framework, we demonstrate that a significant net atomic current arises when the lattice driving frequency is tuned to an integer fraction of the Bloch frequency, while the current averages to nearly zero away from such a resonance. In the single-particle regime, the resonance width scales inversely with the averaging time, thereby setting a fundamental Fourier-limited bound on the measurement's sensitivity. Strikingly, our numerical simulations demonstrate that this Fourier limit - a fundamental barrier in the non-interacting system - can be surpassed by introducing weak interactions between atoms. In the interacting regime, the sensitivity surpasses the Fourier-limited scaling with the averaging time, achieving an improvement of at least two orders of magnitude over the single-particle scenario, and exceeding the performance of previously proposed ultracold-atom-based angular accelerometers. These findings pave the way for developing new atomic-current-based inertial sensors with interaction-enhanced sensitivity.

Keywords

Cite

@article{arxiv.2605.02048,
  title  = {Enhancing supercurrent-based inertial sensing via interactions in atomtronic angular accelerometers},
  author = {S. Carmona-López and A. Matos-Abiague and F. Isaule and L. Morales-Molina},
  journal= {arXiv preprint arXiv:2605.02048},
  year   = {2026}
}

Comments

27 pages, 8 figures

R2 v1 2026-07-01T12:47:42.888Z