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Main Authors: Sloman, Sara, Van Butcher, J., Raman, Chandra
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.03970
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author Sloman, Sara
Van Butcher, J.
Raman, Chandra
author_facet Sloman, Sara
Van Butcher, J.
Raman, Chandra
contents We have investigated kinematic reversibility in a cold atom system under strongly overdamped conditions. In such systems, inertia is negligible, and for noninteracting rigid particles, inverting the external force causes a perfect reversal of individual particle trajectories. We used a magneto-optical trap (MOT) as a model low Reynolds number fluid and show the kinematic reversibility survives in the presence of interparticle interactions. In our experiment, we applied controlled external forces via a linearly ramped magnetic bias field and monitored the resulting cloud dynamics. Despite the complex three-dimensional rearrangement induced by the forces, the system exhibits precise reversibility when the force is reversed, consistent with Purcell's framework for kinematic reversibility in low Reynolds number hydrodynamics. Reversibility was not universal,however-- under certain MOT alignment conditions we have also observed clear deviations associated with system hysteresis. Our work shows that strongly dissipative cold atom fluids are a versatile and rich platform for exploring overdamped dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2605_03970
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Kinematic reversibility in a low Reynolds number cold atom fluid
Sloman, Sara
Van Butcher, J.
Raman, Chandra
Atomic Physics
We have investigated kinematic reversibility in a cold atom system under strongly overdamped conditions. In such systems, inertia is negligible, and for noninteracting rigid particles, inverting the external force causes a perfect reversal of individual particle trajectories. We used a magneto-optical trap (MOT) as a model low Reynolds number fluid and show the kinematic reversibility survives in the presence of interparticle interactions. In our experiment, we applied controlled external forces via a linearly ramped magnetic bias field and monitored the resulting cloud dynamics. Despite the complex three-dimensional rearrangement induced by the forces, the system exhibits precise reversibility when the force is reversed, consistent with Purcell's framework for kinematic reversibility in low Reynolds number hydrodynamics. Reversibility was not universal,however-- under certain MOT alignment conditions we have also observed clear deviations associated with system hysteresis. Our work shows that strongly dissipative cold atom fluids are a versatile and rich platform for exploring overdamped dynamics.
title Kinematic reversibility in a low Reynolds number cold atom fluid
topic Atomic Physics
url https://arxiv.org/abs/2605.03970