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Main Authors: Gao, Xin-Yuan, Yan, Yangqian
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.12204
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author Gao, Xin-Yuan
Yan, Yangqian
author_facet Gao, Xin-Yuan
Yan, Yangqian
contents Two-body dissipation due to chemical reactions occurs in both ultracold fermionic and bosonic molecular gases. Despite recent advances in achieving quantum degeneracy, the loss dynamics are typically described phenomenologically using rate equations, often assuming thermalization during chemical reactions. From the first principles, we analyze particle loss, temperature evolution, and momentum distributions in single-component Fermi gases using the inelastic quantum Boltzmann equation. Our results prove that the conventional two-body loss model is valid for trapped systems, though it fails to describe the dynamics in homogeneous systems accurately. Interestingly, we find that systems prepared near or above quantum degeneracy can thermalize spontaneously, even in the absence of elastic collisions, while systems initialized deep in degeneracy display non-equilibrium behavior. Our calculations are in good agreement with recent experimental data from trapped systems and could be further tested in atomic systems with induced two-body loss in box potentials.
format Preprint
id arxiv_https___arxiv_org_abs_2410_12204
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Fate of thermalization of ultracold fermions with two-body dissipation
Gao, Xin-Yuan
Yan, Yangqian
Quantum Gases
Two-body dissipation due to chemical reactions occurs in both ultracold fermionic and bosonic molecular gases. Despite recent advances in achieving quantum degeneracy, the loss dynamics are typically described phenomenologically using rate equations, often assuming thermalization during chemical reactions. From the first principles, we analyze particle loss, temperature evolution, and momentum distributions in single-component Fermi gases using the inelastic quantum Boltzmann equation. Our results prove that the conventional two-body loss model is valid for trapped systems, though it fails to describe the dynamics in homogeneous systems accurately. Interestingly, we find that systems prepared near or above quantum degeneracy can thermalize spontaneously, even in the absence of elastic collisions, while systems initialized deep in degeneracy display non-equilibrium behavior. Our calculations are in good agreement with recent experimental data from trapped systems and could be further tested in atomic systems with induced two-body loss in box potentials.
title Fate of thermalization of ultracold fermions with two-body dissipation
topic Quantum Gases
url https://arxiv.org/abs/2410.12204