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Main Authors: Poparić, Ivan, Markić, Leandra Vranješ, Boronat, Jordi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.12390
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author Poparić, Ivan
Markić, Leandra Vranješ
Boronat, Jordi
author_facet Poparić, Ivan
Markić, Leandra Vranješ
Boronat, Jordi
contents Using density functional theory, we have theoretically studied the formation and the stability of vortices in quantum liquid droplets composed of a mixture of hyperfine states of potassium. Following the experimental setup that produced quantum droplets for the first time, we work with squeezed drops that are compressed in one direction. By squeezing the drops even more, towards a quasi-two dimensional geometry, we study the minimum atom number able to show a stable vortex and obtain that this number is significantly smaller than previous predictions for spherical droplets. The reduction of the critical atom number for forming a stable vortex could make their experimental observation in these droplets, which is still lacking, more feasible. Contrary to results obtained in heteronuclear mixtures, where the energetically preferred vortices are partially filled with the species not participating in the rotation, our results show a relevant stability island of fully empty vortices. Increasing the number of particles in the drop and the speed of rotation, we estimate the transition line between empty and filled vortices.
format Preprint
id arxiv_https___arxiv_org_abs_2510_12390
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Empty and filled vortices in squeezed 39K Bose-Bose liquid drops
Poparić, Ivan
Markić, Leandra Vranješ
Boronat, Jordi
Quantum Gases
Using density functional theory, we have theoretically studied the formation and the stability of vortices in quantum liquid droplets composed of a mixture of hyperfine states of potassium. Following the experimental setup that produced quantum droplets for the first time, we work with squeezed drops that are compressed in one direction. By squeezing the drops even more, towards a quasi-two dimensional geometry, we study the minimum atom number able to show a stable vortex and obtain that this number is significantly smaller than previous predictions for spherical droplets. The reduction of the critical atom number for forming a stable vortex could make their experimental observation in these droplets, which is still lacking, more feasible. Contrary to results obtained in heteronuclear mixtures, where the energetically preferred vortices are partially filled with the species not participating in the rotation, our results show a relevant stability island of fully empty vortices. Increasing the number of particles in the drop and the speed of rotation, we estimate the transition line between empty and filled vortices.
title Empty and filled vortices in squeezed 39K Bose-Bose liquid drops
topic Quantum Gases
url https://arxiv.org/abs/2510.12390