通过复杂朗温模拟实现旋转玻色-爱因斯坦凝聚体中量子化涡旋结构的有限温度稳定性

arXiv - PHYS - Quantum Gases Pub Date : 2024-09-12 DOI:arxiv-2409.07791

Kimberlee Keithley, Kris T. Delaney, Glenn H. Fredrickson

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引用次数: 0

摘要

在有限温度下，我们使用复朗格文采样法评估了旋转玻色-爱因斯坦凝聚态中量子化涡旋模式的热力学稳定性。我们构建了温度-旋转频率相图，并发现在较低的旋转速度下，量子波动和热波动会使涡旋稳定下来。相干态场理论表示的虚时间路径积分能够有效地模拟有限温度下的大型系统，而复兰格文模拟方案绕过了复值相干态场以及描述固体旋转的规势所产生的符号问题。通过场算子，我们可以生成云中粒子和动量密度的高分辨率图像。量子化涡旋在密度图像上显示为暗点，云动量矢量图详细环绕每个涡旋。

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Finite temperature stability of quantized vortex structures in rotating Bose-Einstein condensates via complex Langevin simulation

The thermodynamic stability of quantized vortex patterns in rotating Bose-Einstein condensates is assessed at finite temperature using complex Langevin sampling. We construct a temperature-rotation frequency phase diagram and find that that vortices are stabilized at lower rotation speeds by the addition of quantum and thermal fluctuations. The coherent states field theoretic representation of the imaginary time path integral enables efficient simulation of large systems at finite temperature, and the complex Langevin simulation scheme bypasses the sign problems that arise from the complex-valued coherent states fields as well as the gauge potential describing solid body rotation. Field operators allow us to generate high-resolution images of particle and momentum density of the cloud. Quantized vortices appear as dark spots on density images, and vector plots of cloud momentum detail circulation around each vortex.

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arXiv - PHYS - Quantum Gases

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