高分辨率观测受太阳黑子自转调节的喷流

IF 2.7 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Tingyu Gou, Rui Liu, Yang Su, Astrid M. Veronig, Hanya Pan, Runbin Luo, Weiqun Gan
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引用次数: 0

摘要

日冕喷流被认为是大规模太阳爆发的缩影。特别是,基拱内的小丝的爆发被认为是喷出射流的触发甚至驱动因素。在这里,我们提出了另一种触发机制,它是基于对一个与小丝和一个M1.2级耀斑相关的井喷喷流的高分辨率H(\α \)观测。在喷出射流过程中,小纤丝基本保持静止,但它被连接两条耀斑带的耀斑环所跨越,这表明嵌入小纤丝的磁弧被撕裂成两部分,上半部分随喷出射流逃逸。在耀斑之后,小纤丝的南端像邻近的纤丝一样扇出,表明小纤丝和纤丝之间进行了质量和磁场交换。在喷出射流之前有一个标准射流。随着H(α)纤维以横扫的方式向单股尖顶移动,标准射流过渡到井喷射流。在较早的C级耀斑中,也出现了类似的从标准射流到喷出射流的过渡模式,然后才形成了细丝。这些纤丝的螺旋形态和横扫方向表明,它们的脚点受到了顺时针旋转两天多的领先太阳黑子的拖拽。在太阳黑子旋转达到角速度峰值(10度/小时-1)后不久,休眠的活跃区域开始产生耀斑,通过旋转的太阳黑子移动磁特征与卫星光斑/孔隙的相互作用,形成了小纤丝。因此,我们认为太阳黑子的旋转在为耀斑和喷流积累自由能以及通过诱导纤丝的横扫运动触发喷流方面起着关键作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

High-Resolution Observation of Blowout Jets Regulated by Sunspot Rotation

High-Resolution Observation of Blowout Jets Regulated by Sunspot Rotation

High-Resolution Observation of Blowout Jets Regulated by Sunspot Rotation

Coronal jets are believed to be the miniature version of large-scale solar eruptions. In particular, the eruption of a minifilament inside the base arch is suggested to be the trigger and even driver of blowout jets. Here, we propose an alternative triggering mechanism, based on high-resolution H\(\alpha \) observations of a blowout jet associated with a minifilament and an M1.2-class flare. The minifilament remains largely stationary during the blowout jet, except that it is straddled by flare loops connecting two flare ribbons, indicating that the magnetic arcade embedding the minifilament has been torn into two parts, with the upper part escaping with the blowout jet. In the wake of the flare, the southern end of the minifilament fans out like neighboring fibrils, indicative of mass and field exchanges between the minifilament and the fibrils. The blowout jet is preceded by a standard jet. With H\(\alpha \) fibrils moving toward the single-strand spire in a sweeping fashion, the standard jet transitions to the blowout jet. A similar pattern of standard-to-blowout jet transition occurs in an earlier C-class flare before the minifilament forms. The spiraling morphology and sweeping direction of these fibrils are suggestive of their footpoints being dragged by the leading sunspot that undergoes clockwise rotation for over two days. Soon after the sunspot rotation reaches a peak angular speed as fast as 10 deg h−1, the dormant active region becomes flare productive, and the minifilament forms through the interaction of moving magnetic features from the rotating sunspot with satellite spots/pores. Hence, we suggest that the sunspot rotation plays a key role in building up free energy for flares and jets and in triggering blowout jets by inducing sweeping motions of fibrils.

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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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