Dynamical Transition of Quantum Vortex-Pair Annihilation in a Bose-Einstein Condensate

arXiv - PHYS - Quantum Gases Pub Date : 2024-07-19 DOI:arxiv-2407.14627

Toshiaki Kanai, Chuanwei Zhang

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Abstract

Understanding the elementary mechanism for the dissipation of vortex energy in quantum liquids is one central issue in quantum hydrodynamics, such as quantum turbulence in systems ranging from neutron stars to atomic condensates. In a two-dimensional (2D) Bose-Einstein condensate (BEC) at zero temperature, besides the vortex drift-out process from the boundary, vortex-antivortex pair can annihilate in the bulk, but controversy remains on the number of vortices involved in the annihilation process. We find there exists a dynamical transition from four-body to three-body vortex annihilation processes with the time evolution in a boundary-less uniform quasi-2D BEC. Such dynamical transition depends on the initial vortex pair density, and occurs when the sound waves generated in the vortex annihilation process surpass a critical energy. With the confinement along the third direction is relaxed in a quasi-2D BEC, the critical sound wave energy decreases due to the 3D vortex line curve and reconnection, shifting the dynamical transition to the early time. Our work reveals an elementary mechanism for the dissipation of vortex energy that may help understand exotic matter and dynamics in quantum liquids.

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玻色-爱因斯坦凝聚态中量子涡对湮灭的动态转变

理解量子液体中涡旋能量耗散的基本机制是量子流体力学的一个核心问题，例如从中子星到原子凝聚态等系统中的量子湍流。在零温下的二维玻色-爱因斯坦凝聚态（BEC）中，除了边界上的涡旋漂出过程外，涡旋-反涡旋对还可以在体中湮灭，但关于湮灭过程中涉及的涡旋数量仍然存在争议。我们发现，在无边界均匀准二维 BEC 中，随着时间的演化，存在着从四体涡旋湮灭过程到三体涡旋湮灭过程的动力学转变。这种动力学转变取决于初始涡旋对密度，并且发生在涡旋湮灭过程中产生的声波超过临界能量时。在准 2DBEC 中，随着沿第三个方向的束缚被放松，临界声波能量会因三维涡线曲线和重连接而降低，从而将动力学转变转移到早期。我们的研究揭示了涡旋能量耗散的基本机制，可能有助于理解量子液体中的奇异物质和动力学。

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arXiv - PHYS - Quantum Gases

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