揭开由涡旋运动驱动的扭曲突出物的解扭过程和向上传质的奥秘

X.F. Zhang, G.P. Zhou, C.L. Jin, Y.Z. Zhang, G.W. Li, Z.H. Shang, L.P. Li, S.B. Yang, S.H. Yang, J.X. Wang
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摘要

日珥或日珥丝是太阳大气中的常见特征,它们包含悬浮在热日冕中的冷色球物质。然而,人们对这些结构错综复杂的拓扑结构及其不稳定性和物质向上转移的驱动机制还不甚了解。研究这些问题对于深入了解太阳活动的基本规律至关重要。本研究旨在分析 2021 年 2 月 10 日观测到的一个特定扭转突出现象,并探索其动态,包括稳定性、运动和物质转移。研究还旨在提出一种基于 "漩涡街不稳定性"(K\'arm\'an Vortex Street instability)的机制来解释该突出的不稳定性。这项研究利用了 1 米新真空太阳望远镜的高分辨率 H$_ alpha $ 观测数据和太阳动力学观测站的空间观测数据。这些观测数据捕捉到了扭曲突出的特征和行为。我们对这些数据进行了分析,以研究该突出物的平衡状态、随后的失稳、涡旋运动、振荡、共振、解捻和向上的质量负荷。我们还探测并测量了突出物周围的流出速度。研究显示,观测到的扭曲突出物在其顶点处呈现出一种拉伸和扭曲的结构,这使它有别于我们熟悉的云状突出物。经过 30 多个小时的平衡期后,该突出物发生了不稳定,导致一系列动态现象,如涡旋运动、振荡、共振、解捻和质量向上转移。因此,来自突出部顶部的物质被向上携带并沉积到上覆的磁弧中。值得注意的是,突出部周围的外流速度超过了 40 千米/秒$^ 基于这些发现,我们首次提出了一种植根于 K\'arm\'an 涡街不稳定性的机制来解释突出部的失稳。估计的典型斯特劳哈尔数(Strouhal Number)为0.23pm 0.06,这与涡旋脱落有关,正如模拟预测的那样,属于K\'arm\'an Vortex Street效应的预期范围。这些发现为了解太阳突出部的动力学和基本拓扑结构提供了新的视角,并揭示了一种以前未知的上层大气质量负载机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Unraveling the untwisting process and upward mass transfer of a twisted prominence driven by vortex motion
Solar filaments or prominences are common features in the Sun's atmosphere that contain cool chromospheric material suspended within the hot corona. However, the intricate topology of these structures and the mechanisms driving their instability and upward material transfer are not well understood. Investigating these issues is essential for gaining insight into the fundamental laws that govern solar activity. This study is to analyze a specific twisted prominence observed on February 10, 2021, and to explore its dynamics, including stability, motion, and material transfer. The study also aims to propose a mechanism, based on the K\'arm\'an Vortex Street instability, to explain the destabilization of the prominence. The study utilizes high-resolution H$_ alpha $ observations from the 1-m New Vacuum Solar Telescope and space-borne observations from the Solar Dynamics Observatory. These observations capture the characteristics and behavior of the twisted prominence. We analyzed the data to investigate the equilibrium state, subsequent destabilization, vortex motion, oscillations, resonations, untwisting, and upward mass loading of the prominence. We also detected and measured the speeds of outflows surrounding the prominence. The study reveals that the observed twisted prominence exhibited a stretched and twisted structure at its apex, distinguishing it from familiar cloudy prominences. Following a period of more than 30 hours in equilibrium, the prominence underwent destabilization, leading to a series of dynamic phenomena, such as vortex motion, oscillations, resonations, untwisting, and the upward transfer of mass. Consequently, material from the top of the prominence was carried upward and deposited into the overlying magnetic arcades. Noteworthy, outflows surrounding the prominence were characterized by speeds exceeding 40 km s$^ Based on these findings, we propose, for the first time, a mechanism rooted in the K\'arm\'an Vortex Street instability to explain the destabilization of the prominence. The estimated typical Strouhal Number of 0.23pm 0.06, which is related to vortex shedding, falls within the expected range for the K\'arm\'an Vortex Street effect, as predicted by simulations. These discoveries provide new insights into the dynamics and fundamental topology of solar prominences and reveal a previously unknown mechanism for mass loading into the upper atmosphere.
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