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Main Authors: Tsarev, D V, Ansimov, D V, Podoshvedov, S A, Alodjants, A P
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.16032
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author Tsarev, D V
Ansimov, D V
Podoshvedov, S A
Alodjants, A P
author_facet Tsarev, D V
Ansimov, D V
Podoshvedov, S A
Alodjants, A P
contents In this work, we consider the feasibility of Schr{ö}dinger cat (SC) and $N00N$ states formation by a convenient bosonic Josephson junction (BJJ) system in two-mode approximation. Starting with purely quantum description of two-mode Bose-Einstein condensate we investigate the effective potential approach that provides an accurate analytical description for the system with a large number of particles. We show that in the zero temperature limit SC states result from a quantum phase transition that occurs when the nonlinear strength becomes comparable with the Josephson coupling parameter. The Wigner function approach demonstrates the growth of the SC state halves separation and formation of $N00N$-like states (a Fock state superposition) with the particle number increase. We examine the possibility to attain the SC state at finite temperatures and a weak dissipation leading to appearing of some critical temperature; it defines the second-order phase transition from classical activation process to the SC state formation through the quantum tunneling phenomenon. Numerical estimations demonstrate that the critical temperature is sufficiently below the temperature of atomic condensation. The results obtained may be useful for experimental observation of SC states with small condensate Josephson junctions.
format Preprint
id arxiv_https___arxiv_org_abs_2507_16032
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Schr{ö}dinger cat state formation in small bosonic Josephson junctions at finite temperatures and dissipation
Tsarev, D V
Ansimov, D V
Podoshvedov, S A
Alodjants, A P
Quantum Physics
In this work, we consider the feasibility of Schr{ö}dinger cat (SC) and $N00N$ states formation by a convenient bosonic Josephson junction (BJJ) system in two-mode approximation. Starting with purely quantum description of two-mode Bose-Einstein condensate we investigate the effective potential approach that provides an accurate analytical description for the system with a large number of particles. We show that in the zero temperature limit SC states result from a quantum phase transition that occurs when the nonlinear strength becomes comparable with the Josephson coupling parameter. The Wigner function approach demonstrates the growth of the SC state halves separation and formation of $N00N$-like states (a Fock state superposition) with the particle number increase. We examine the possibility to attain the SC state at finite temperatures and a weak dissipation leading to appearing of some critical temperature; it defines the second-order phase transition from classical activation process to the SC state formation through the quantum tunneling phenomenon. Numerical estimations demonstrate that the critical temperature is sufficiently below the temperature of atomic condensation. The results obtained may be useful for experimental observation of SC states with small condensate Josephson junctions.
title Schr{ö}dinger cat state formation in small bosonic Josephson junctions at finite temperatures and dissipation
topic Quantum Physics
url https://arxiv.org/abs/2507.16032