Related papers: Persistent currents in ultracold gases

Persistent currents in ultracold gases

URL: http://arxiv.org/abs/2410.17318v1
Date: Tue, 22 Oct 2024 18:00:03 GMT
Title: Persistent currents in ultracold gases
Authors: J. Polo, W. J. Chetcuti, T. Haug, A. Minguzzi, K. Wright, L. Amico,
Abstract summary: Persistent currents flowing in spatially closed tracks define one of the most iconic concepts in mesoscopic physics. They have been studied in solid-state platforms such as superfluids, superconductors and metals. We discuss how persistent currents can form the basis of new technological applications like matter-wave gyroscopes and interferometers.
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Abstract: Persistent currents flowing in spatially closed tracks define one of the most iconic concepts in mesoscopic physics. They have been studied in solid-state platforms such as superfluids, superconductors and metals. Cold atoms trapped in magneto-optical toroidal circuits and driven by suitable artificial gauge fields allow us to study persistent currents with unprecedented control and flexibility of the system's physical conditions. Here, we review persistent currents of ultracold matter. Capitalizing on the remarkable progress in driving different atomic species to quantum degeneracy, persistent currents of single or multicomponent bosons/fermions, and their mixtures can be addressed within the present experimental know-how. This way, fundamental concepts of quantum science and many-body physics, like macroscopic quantum coherence, solitons, vortex dynamics, fermionic pairing and BEC-BCS crossover can be studied from a novel perspective. Finally, we discuss how persistent currents can form the basis of new technological applications like matter-wave gyroscopes and interferometers.

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