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The Power-Law Distribution of Flare Kernels and Fractal Current Sheets in a Solar Flare

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 نشر من قبل Naoto Nishizuka
 تاريخ النشر 2013
  مجال البحث فيزياء
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 تأليف N. Nishizuka




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We report a detailed examination of the fine structure inside flare ribbons and the temporal evolution of this fine structure during the X2.5 solar flare that occurred on 2004 November 10. We examine elementary bursts of the C IV (1550{AA}) emission lines seen as local transient brightenings inside the flare ribbons in the ultraviolet (1600{AA}) images taken with Transition Region and Coronal Explorer, and we call them C IV kernels. This flare was also observed in Ha with the Sartorius 18 cm Refractor telescope at Kwasan observatory, Kyoto University, and in hard X-rays (HXR) with Reuven Ramaty High Energy Solar Spectroscopic Imager. Many C IV kernels, whose sizes were comparable to or less than 2, were found to brighten successively during the evolution of the flare ribbon. The majority of them were well correlated with the Ha kernels in both space and time, while some of them were associated with the HXR emission. These kernels were thought to be caused by the precipitation of nonthermal particles at the footpoints of the reconnecting flare loops. The time profiles of the C IV kernels showed intermittent bursts, whose peak intensity, duration, and time interval were well described by power-law distribution functions. This result is interpreted as evidence for self-organized criticality in avalanching behavior in a single flare event, or for fractal current sheets in the impulsive reconnection region.



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