扰动玻色-爱因斯坦凝聚态中的动态涡旋产生和量子湍流

IF 1.7 4区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY Few-Body Systems Pub Date : 2024-02-20 DOI:10.1007/s00601-024-01879-4

Lauro Tomio, Anacé N. da Silva, S. Sabari, R. Kishor Kumar

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引用次数: 0

摘要

通过考虑两种不同的时变方法，报告了周期性扰动的准二维（q2D）玻色-爱因斯坦凝聚体中出现的动态涡旋产生和量子湍流。在这两种情况下，都是通过求解相应的二维均场格罗斯-皮塔耶夫斯基形式主义进行动力学模拟的。(1) 在第一个模型中，双质量不平衡系统受到随时间变化的椭圆外部势的轻微扰动。(2) 在第二个模型中，对于限制在 q2D 几何结构中的单偶极物种，在凝结物中施加一个圆周运动的外部高斯形障碍物，其径向位置固定，旋转速度恒定，足以产生涡旋-反涡旋对。在第一种情况下，涡旋图案会在足够长的时间后结晶，而在第二种情况下，涡旋对仍会在流体内部动态地相互作用。在这两种情况下，都可以在某个短时间间隔内观察到湍流的柯尔莫哥洛夫频谱缩放定律特征。

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Dynamical Vortex Production and Quantum Turbulence in Perturbed Bose–Einstein Condensates

Dynamical vortex production and quantum turbulence emerging in periodic perturbed quasi-two-dimensional (q2D) Bose–Einstein condensates are reported by considering two distinct time-dependent approaches. In both cases, dynamical simulations were performed by solving the corresponding 2D mean-field Gross-Pitaevskii formalism. (1) In the first model, a binary mass-imbalanced system is slightly perturbed by a stirring time-dependent elliptic external potential. (2) In the second model, for single dipolar species confined in q2D geometry, a circularly moving external Gaussian-shaped obstacle is applied in the condensate, at a fixed radial position and constant rotational speed, enough for the production of vortex–antivortex pairs. Within the first case, vortex patterns are crystalized after enough longer period, whereas in the second case, the vortex pairs remains interacting dynamically inside the fluid. In both cases, the characteristic Kolmogorov spectral scaling law for turbulence can be observed at some short time interval.

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来源期刊

Few-Body Systems 物理-物理：综合

CiteScore

2.90

自引率

18.80%

发文量

审稿时长

6-12 weeks

期刊介绍： The journal Few-Body Systems presents original research work – experimental, theoretical and computational – investigating the behavior of any classical or quantum system consisting of a small number of well-defined constituent structures. The focus is on the research methods, properties, and results characteristic of few-body systems. Examples of few-body systems range from few-quark states, light nuclear and hadronic systems; few-electron atomic systems and small molecules; and specific systems in condensed matter and surface physics (such as quantum dots and highly correlated trapped systems), up to and including large-scale celestial structures. Systems for which an equivalent one-body description is available or can be designed, and large systems for which specific many-body methods are needed are outside the scope of the journal. The journal is devoted to the publication of all aspects of few-body systems research and applications. While concentrating on few-body systems well-suited to rigorous solutions, the journal also encourages interdisciplinary contributions that foster common approaches and insights, introduce and benchmark the use of novel tools (e.g. machine learning) and develop relevant applications (e.g. few-body aspects in quantum technologies).