Noise-dissipation Correlated Dynamics of a Double-well Bose-Einstein Condensate-reservoir System

IF 0.5 Q4 PHYSICS, MULTIDISCIPLINARY

Jordan Journal of Physics Pub Date : 2022-12-31 DOI:10.47011/15.5.2

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Abstract

Abstract: In this work, we study the dissipative dynamics of a double-well Bose-Einstein condensate (BEC) out-coupled to reservoir at each side of its trap. The sub-system comprises of a simple Bose-Hubbard model, where the interplay of atom-tunneling current and inter-particle interaction are the main quantum features. The contact with two separate heat baths causes dissipation and drives the system into a non-equilibrium state. The system is well described by the Generalized Quantum Heisenberg-Langevin equation. We considered two Markovian dissipative BEC systems based on (i) the mean-field model (MF), where the internal noise has been averaged out and (ii) the noise-correlated model (FDT). Physical quantities, such as population imbalance, coherence and entanglement of the system, are computed for the models. The two-mode BEC phases, such as the quantum tunneling state and the macroscopic quantum-trapping state, evolved into complicated dynamics by controlling the non-linear interaction and dissipation strengths. We found that many important quantum features produced by the noise-correlated FDT model are not captured by the mean-field model. Keywords: Double-well BEC, Dissipation, Noise, Markovian, Non-Markovian, Fixed points. PACS: 03.75 Lm, 03.65 Yz, 03.75 Gg, 05.

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双井Bose-Einstein凝析油气藏系统的噪声耗散相关动力学

摘要：在这项工作中，我们研究了双阱玻色-爱因斯坦凝聚体（BEC）在其阱两侧与储层耦合的耗散动力学。该子系统由一个简单的玻色-哈伯德模型组成，其中原子隧穿电流和粒子间相互作用的相互作用是主要的量子特征。与两个独立的热浴的接触导致耗散，并将系统驱动到非平衡状态。广义量子海森堡-朗之万方程很好地描述了该系统。基于（i）平均场模型（MF）和（ii）噪声相关模型（FDT），我们考虑了两个马尔可夫耗散BEC系统，其中内部噪声已被平均。为模型计算了物理量，如种群不平衡、系统的相干和纠缠。双模BEC相，如量子隧穿态和宏观量子捕获态，通过控制非线性相互作用和耗散强度，演化为复杂的动力学。我们发现，噪声相关FDT模型产生的许多重要量子特征并没有被平均场模型捕获。关键词：双阱BEC，耗散，噪声，马尔可夫，非马尔可夫，不动点。PACS：03.75 Lm，03.65 Yz，03.75 Gg，05。

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来源期刊

Jordan Journal of Physics PHYSICS, MULTIDISCIPLINARY-

CiteScore

0.90

自引率

14.30%

发文量