The Multifaceted M1.7 GOES-class Flare Event of 21 April 2023 in AR13283

IF 2.7 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Solar Physics Pub Date : 2024-08-14 DOI:10.1007/s11207-024-02355-2
A. Elmhamdi, A. Marassi, P. Romano, L. Contarino, W. AlShehri, C. Monstein
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Abstract

On 21 April 2023, a significant M1.7 solar flare erupted from Active Region 13283, accompanied by a filament eruption and a full-halo Coronal Mass Ejection, which reached Earth on 23 April, triggering a severe geomagnetic storm, with Kp reaching 8 (G4) and Dst plummeting to −212 nT together with a sharply distinguished long-lasting negative double-dip behavior of the \(z\)-component of the interplanetary magnetic field. This event led to remarkable auroral displays, even at mid-latitudes in Europe. The flare-induced filament eruption caused distinct intensity dimming in the solar corona, observed in specific EUV wavelengths. We observed the dimming region growing at its fastest rate before the flare reached its peak of intensity. Notably, the proximity of the flare to a large southern coronal hole influenced the expansion and propagation of the coronal mass ejection toward Earth, probably impacting the solar wind speed and density. Additionally, we observed a sudden expansion of the coronal hole during the flare, leading us to speculating that the adjacent flare may have further stimulated the flow of solar-wind particles along the open magnetic-field lines. In accordance with the severe Dst-index disturbance, we also report changes in the potential of the pipeline of an Italian energy infrastructure company with respect to the surrounding soil as well as double-dip variation in the H-component of the terrestial magnetic field observed locally (reminiscent to what reported in Dst-index and IMF Bz) temporal profiles, confirming the effects of the geomagnetic storm at Italy mid-latitudes. Several solar radio events have been observed too. Therefore this study provides insights into the dynamic solar phenomena and their potential geomagnetic implications.

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2023 年 4 月 21 日发生在 AR13283 的多层面 M1.7 GOES 级耀斑事件
2023 年 4 月 21 日,活动区 13283 爆发了一个 M1.7 级太阳耀斑,同时伴有细丝爆发和全光晕日冕物质抛射,于 4 月 23 日到达地球,引发了严重的地磁暴,Kp 达到 8 (G4),Dst 骤降至 -212 nT,行星际磁场的 \(z\)- 分量出现了明显的持久负双倾行为。这一事件导致了令人瞩目的极光现象,即使在欧洲的中纬度地区也是如此。耀斑诱发的灯丝爆发导致日冕出现明显的强度减弱,这是在特定的超紫外波长下观测到的。我们观察到,在耀斑达到强度峰值之前,变暗区域以最快的速度增长。值得注意的是,耀斑靠近南部的一个大型日冕洞影响了日冕物质抛射的扩展和向地球的传播,可能对太阳风的速度和密度产生了影响。此外,我们还观测到日冕洞在耀斑期间突然扩大,这让我们猜测邻近的耀斑可能进一步刺激了太阳风粒子沿开放磁场线的流动。根据严重的 Dst 指数扰动,我们还报告了一家意大利能源基础设施公司的管道相对于周围土壤的电位变化,以及在当地观测到的陆地磁场 H 分量的双浸变化(与 Dst 指数和 IMF Bz 中报告的情况相似),证实了意大利中纬度地区地磁暴的影响。此外,还观测到一些太阳射电事件。因此,这项研究有助于深入了解动态太阳现象及其对地磁的潜在影响。
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来源期刊
Solar Physics
Solar Physics 地学天文-天文与天体物理
CiteScore
5.10
自引率
17.90%
发文量
146
审稿时长
1 months
期刊介绍: Solar Physics was founded in 1967 and is the principal journal for the publication of the results of fundamental research on the Sun. The journal treats all aspects of solar physics, ranging from the internal structure of the Sun and its evolution to the outer corona and solar wind in interplanetary space. Papers on solar-terrestrial physics and on stellar research are also published when their results have a direct bearing on our understanding of the Sun.
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