We propose and numerically validate an experimentally feasible on-demand protocol for the nucleation and manipulation of stable quantum vortex rings in trapped Bose-Einstein condensates. The method relies on sweeping a laser-sheet barrier that locally constricts the superflow and triggers vortex-ring formation. By tuning the barrier height and width, and by scanning the barrier velocity, we identify the onset of periodic generation of vortex rings above the critical velocity and achieve direct, deterministic control over the ring nucleation position, radius, and hence propagation speed. After its formation, ad hoc optical potentials are applied to reshape the vortex ring, creating clean Kelvin-wave excitations. Our results provide a foundation for systematic studies of three-dimensional vortices in atomic superfluids and open the door to tailored vortex dynamics and interactions, enabling controlled access to quantum turbulence.

Reproducible nucleation and control of stable quantum vortex rings in Bose-Einstein condensates / G. Iori, K.X.. - In: PHYSICAL REVIEW RESEARCH. - ISSN 2643-1564. - 8:2(2026 Jun 05), pp. L022043.1-L022043.8. [10.1103/qvg7-mr18]

Reproducible nucleation and control of stable quantum vortex rings in Bose-Einstein condensates

G. Iori
Primo
;
W.J. Kwon;D.E. Galli
Penultimo
;
2026

Abstract

We propose and numerically validate an experimentally feasible on-demand protocol for the nucleation and manipulation of stable quantum vortex rings in trapped Bose-Einstein condensates. The method relies on sweeping a laser-sheet barrier that locally constricts the superflow and triggers vortex-ring formation. By tuning the barrier height and width, and by scanning the barrier velocity, we identify the onset of periodic generation of vortex rings above the critical velocity and achieve direct, deterministic control over the ring nucleation position, radius, and hence propagation speed. After its formation, ad hoc optical potentials are applied to reshape the vortex ring, creating clean Kelvin-wave excitations. Our results provide a foundation for systematic studies of three-dimensional vortices in atomic superfluids and open the door to tailored vortex dynamics and interactions, enabling controlled access to quantum turbulence.
Settore PHYS-03/A - Fisica sperimentale della materia e applicazioni
   Quantum Vortex Simulator: from fundamental properties toward engineering mobility
   QUAVADIS
   European Commission
   Horizon Europe Framework Programme - European Research Council - HORIZON ERC Grants
   101076129
5-giu-2026
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2434/1261575
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