Related papers: Interaction-induced dissipative quantum phase transition in a head-to-tail atomic Josephson junction

Interaction-induced dissipative quantum phase transition in a head-to-tail atomic Josephson junction

URL: http://arxiv.org/abs/2407.02890v3
Date: Thu, 17 Oct 2024 01:58:06 GMT
Title: Interaction-induced dissipative quantum phase transition in a head-to-tail atomic Josephson junction
Authors: Koichiro Furutani, Luca Salasnich,
Abstract summary: We propose a dissipative phase transition in a head-to-tail Bose Josephson junction. We show that the interatomic interaction strength plays the role of the damping parameter. We argue that tight transverse confinement of the quasi-one-dimensional atomic gas allows us to reach the insulating phase.
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Abstract: We propose a dissipative phase transition in a head-to-tail Bose Josephson junction. The quantum phase transition has the same origin as the one in a resistively shunted Josephson junction, but the intrinsic momentum coupling between the Josephson mode and the bath modes enables us to observe the dissipative phase transition without any synthetic dissipation. We show that the interatomic interaction strength plays the role of the damping parameter. Consequently, in contrast to a resistively shunted Josephson circuit, the Bose Josephson junction can exhibit an insulating phase in a wider parameter region by increasing the repulsive interaction strength, which is robust against nonperturbative effects. We argue that tight transverse confinement of the quasi-one-dimensional atomic gas allows us to reach the insulating phase.

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