Sun-as-a-star Analysis of the X1.6 Flare on 2023 August 5: Dynamics of Post-flare Loops in Spatially Integrated Observational Data

arXiv - PHYS - Solar and Stellar Astrophysics Pub Date : 2024-09-11 DOI:arxiv-2409.07630

Takato Otsu, Ayumi Asai, Kai Ikuta, Kazunari Shibata

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Abstract

Post-flare loops are loop-like plasmas observed during the decay phase of solar flares, and they are expected to exist for stellar flares. However, it is unclear how post-flare loops are observed in stellar flares' cases. To clarify behaviors of post-flare loops in spatially integrated data, we performed the Sun-as-a-star analysis of the X1.6 flare that occurred on 2023 August 5, using GOES X-ray flux ($\sim10^7$ K), extreme ultraviolet (EUV) images taken by Atmospheric Imaging Assembly onboard the Solar Dynamic Observatory ($\ge10^{4.9}$ K) and H$\alpha$ data taken by Solar Dynamics Doppler Imager on board the Solar Magnetic Activity Research Telescope at Hida Observatory, Kyoto University ($\sim10^4$ K). As a result, this flare showed signatures corresponding to the important dynamics of the post-flare loops even in the spatially integrated data: (1) The H$\alpha$ light curve showed two distinct peaks corresponding to the flare ribbons and the post-flare loops. The plasma cooling in the post-flare loops generated different peak times in soft X-rays, EUV, and H$\alpha$ light curves. (2) Downflows were confirmed as simultaneous redshifted/blueshifted absorptions in the H$\alpha$ spectra. (3) The apparent rise of post-flare loops was recognized as a slowing of the decay for the H$\alpha$ light curve. These results are keys to investigating stellar post-flare loops with spatially integrated data. We also discuss the dependence of our results on flare locations and their possible applications to stellar observations.

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2023 年 8 月 5 日 X1.6 耀斑的太阳-恒星分析：空间综合观测数据中的耀斑后环流动力学

耀斑后环路是在太阳耀斑衰变阶段观测到的环状等离子体，预计恒星耀斑也会存在这种环路。然而，在恒星耀斑中如何观测到耀斑后环路尚不清楚。为了澄清空间综合数据中耀斑后环路的行为，我们对2023年8月5日发生的X1.6耀斑进行了太阳即恒星分析，使用了GOES的X射线通量（$\sim10^7$ K）、太阳动力学观测站上大气成像组件拍摄的极紫外（EUV）图像（$\ge10^{4.9}$ K）和京都大学飞騨天文台太阳磁活动研究望远镜上的太阳动力学多普勒成像仪拍摄的 H$\alpha$ 数据（$\sim10^4$ K）。因此，即使在空间综合数据中，该耀斑也显示出与耀斑后环路的重要动态相对应的特征：（1）H$\alpha$光曲线显示出与耀斑带和耀斑后环路相对应的两个明显峰值。耀斑后环中的等离子体冷却在软 X 射线、EUV 和 H$\alpha$ 光曲线中产生了不同的峰值时间。(2) 在H$\alpha$光谱中，下流被证实为同时的红移/蓝移吸收。(3) 彗星后环路的明显崛起被认为是 H$\alpha$ 光曲线衰减的减缓。这些结果是利用空间综合数据研究恒星 "辉后环 "的关键。我们还讨论了我们的结果对耀斑位置的依赖性及其在恒星观测中的可能应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Solar and Stellar Astrophysics

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