Related papers: Dissipation Driven Coherent Dynamics Observed in Bose-Einstein Condensates

Dissipation Driven Coherent Dynamics Observed in Bose-Einstein Condensates

URL: http://arxiv.org/abs/2408.03815v1
Date: Wed, 7 Aug 2024 14:51:34 GMT
Title: Dissipation Driven Coherent Dynamics Observed in Bose-Einstein Condensates
Authors: Ye Tian, Yajuan Zhao, Yue Wu, Jilai Ye, Shuyao Mei, Zhihao Chi, Tian Tian, Ce Wang, Zhe-Yu Shi, Yu Chen, Jiazhong Hu, Hui Zhai, Wenlan Chen,
Abstract summary: We report the first experimental observation of dissipation-driven coherent quantum many-body oscillation. This oscillation is manifested as the coherent exchange of atoms between the thermal and the condensate components. Our work introduces a highly controllable dissipation as a new tool to control quantum many-body dynamics.
Score: 9.805141457983138
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We report the first experimental observation of dissipation-driven coherent quantum many-body oscillation, and this oscillation is manifested as the coherent exchange of atoms between the thermal and the condensate components in a three-dimensional partially condensed Bose gas. Firstly, we observe that the dissipation leads to two different atom loss rates between the thermal and the condensate components, such that the thermal fraction increases as dissipation time increases. Therefore, this dissipation process serves as a tool to uniformly ramp up the system's temperature without introducing extra density excitation. Subsequently, a coherent pair exchange of atoms between the thermal and the condensate components occurs, resulting in coherent oscillation of atom numbers in both components. This oscillation, permanently embedded in the atom loss process, is revealed clearly when we inset a duration of dissipation-free evolution into the entire dynamics, manifested as an oscillation of total atom number at the end. Finally, we also present a theoretical calculation to support this physical mechanism, which simultaneously includes dissipation, interaction, finite temperature, and harmonic trap effects. Our work introduces a highly controllable dissipation as a new tool to control quantum many-body dynamics.

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