Feasibility of ground-based shell-shaped BECs
ORAL
Abstract
Many-body systems confined in shells have recently experienced a huge progress offered by ongoing experiments in orbital microgravity, which have already made crucial steps towards creating the first shell-shaped Bose-Einstein condensate (BEC) [1]. However, in principle there are two complementary methods for realization of such shells in ground-based laboratories: (i) a harmonically trapped dual-component mixture with equal trap frequencies combined with tunable inter-component interaction [2], and (ii) a single-component BEC in a bichromatic optical dipole trap where gravity is compensated by a magnetic field gradient.
To analyze both setups and understand whether stable shell-shaped BECs are feasible, we evaluate suitable atomic species, laser setups, and parameter thresholds which are required to create closed shells. The latter is especially important, as shell-shaped BECs tend to easily open up as soon as the system deviates from the ideal case.
[1] R. A. Carollo et al., arXiv:2108.05880 (2021).
[2] A. Wolf et al., arXiv:2110.15247 (2021).
To analyze both setups and understand whether stable shell-shaped BECs are feasible, we evaluate suitable atomic species, laser setups, and parameter thresholds which are required to create closed shells. The latter is especially important, as shell-shaped BECs tend to easily open up as soon as the system deviates from the ideal case.
[1] R. A. Carollo et al., arXiv:2108.05880 (2021).
[2] A. Wolf et al., arXiv:2110.15247 (2021).
*This project is supported by the German Space Agency (DLR) with funds provided by the Federal Ministry for Economic Affairs and Energy (BMWi) due to an enactment of the German Bundestag under Grant Nos. 50WP1705 (BECCAL), 50WM1862 (CAL), and 50WM2060 (CARIOQA).
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Presenters
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Alexander Wolf
- Institute of Quantum Technologies, German Aerospace Center