确定能量低于和高于 100 MeV 的高能太阳质子事件的特征

IF 2.7 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Dheyaa Ameri, Eino Valtonen, Amjad Al-Sawad, Rami Vainio
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引用次数: 0

摘要

我们分析了1996-2022年间发生的58次高能质子事件。在58个事件中,有32个(55%)的质子能量达到了\(\sim 68\) MeV,但没有达到100 MeV。在其余26个事件中,质子能量超过了100 MeV。我们研究了这些质子事件特征的差异,以及它们与太阳和行星际现象的关联,以加深对质子源和加速过程的理解。与 \(>100\) MeV质子事件相关的日冕物质抛射(CMEs)似乎平均比与\(< 100\) MeV质子事件相关的CMEs能量更高。在100MeV质子事件中,软X射线(SXR)耀斑的峰值和综合通量(通量)更高,但耀斑的上升时间几乎没有差别。在大部分(> 100\ )MeV质子事件中,质子是在SXR耀斑的上升阶段释放的,而在大部分(< 100\ )MeV事件中,质子释放发生在SXR耀斑的峰值之后。我们建立了CME速度VCME和SXR峰值通量Fpk或总通量Fi的限值,这有助于我们区分两组事件。VCME \(> 1000\) km s-1 和 F\(_{mathrm{pk}} > 5 \cdot 10^{-5} \) W m-2 的太阳爆发很有可能产生 \(> 100\) MeV 的质子事件。另一方面,V(_{\mathrm{CME}} > 900\) km s-1和F(_{i} <5 \cdot 10^{-4}\) J m-2的爆发,以及V(_{ \mathrm{CME}} < 900\) km s-1的爆发,无论SXR总通量如何,都很有可能产生(< 100\) MeV的质子事件。所有质子事件都与十余度的III型射电暴有关,其中大多数都与公制波长或十余度-八度(DH)波长或两者的II型射电暴有关。在50%的\(<100\) MeV质子事件中观测到了公制和DH-II型发射,而在\(>100\) MeV事件中观测到了88%的公制和DH-II型发射。我们的分析表明,大多数(>100)MeV事件中的质子都是在DH-II型射电暴发生之前在日冕低层(((\leq 3.0)R⊙)释放的。我们的结论是,大多数(<100\)MeV事件中的质子是被耀斑再连接过程或日冕低处的冲击加速的,并可能在日冕高处的CME冲击中经历再加速,表现为DH-Type II射电辐射。在(<100)MeV事件中,质子主要在日冕高度(>3)R⊙的CME冲击中被加速。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Characterizing High-Energy Solar Proton Events with Energies Below and Above 100 MeV

We analyzed 58 high-energy proton events that occurred during the years 1996 – 2022. In 32 out of the 58 (55%) events, the proton energies extended up to \(\sim 68\) MeV but did not reach 100 MeV. In the remaining 26 events, the proton energies exceeded 100 MeV. We studied the differences in the characteristics of these proton events and their associations with solar and interplanetary phenomena to improve understanding proton sources and acceleration processes.

The coronal mass ejections (CMEs) associated with \(>100\) MeV proton events appeared to be, on average, more energetic than those associated with \(< 100\) MeV proton events. The peak and integrated fluxes (fluence) of the soft X-ray (SXR) flares were higher in > 100 MeV proton events, but there was almost no difference in the rise times of the flares. In a major part of the \(> 100\) MeV proton events, protons were released over the rise phase of the SXR flares, whereas in most of the \(<100\) MeV events the proton releases occurred after the peak of the SXR flares. We established limits for the CME speed VCME and SXR peak flux Fpk or total fluence Fi, which helped us to distinguish the events in the two groups. Solar eruptions with VCME \(> 1000\) km s−1 and F\(_{\mathrm{pk}} > 5 \cdot 10^{-5} \) W m−2 had a high probability to produce proton events of \(> 100\) MeV. On the other hand, eruptions with V\(_{\mathrm{CME}} > 900\) km s−1 and F\(_{i} <5 \cdot 10^{-4} \) J m−2 and eruptions with V\(_{ \mathrm{CME}} < 900\) km s−1 irrespective of the SXR total fluence were very likely to produce proton events of \(< 100\) MeV.

All proton events were associated with decametric Type III radio bursts, and most of them had Type II bursts associations either in metric or decametric–hectometric (DH) wavelengths or both. Both metric- and DH-Type II emissions were observed in 50% of \(<100\) MeV proton events while they were observed in 88% of \(>100\) MeV events. Our analysis showed that protons in most of the \(>100\) MeV events were released low in the corona (\(\leq 3.0\) R) before the onsets of the DH-Type II radio bursts. Conversely, protons in most of the \(<100\) MeV events were released higher in the corona (\(>3\) R) and after the DH-Type II onsets.

We conclude that protons in most of the \(> 100\) MeV events are accelerated either by the flare reconnection processes or by shocks low in the corona and could undergo reacceleration higher in the corona in CME shocks manifested in DH-Type II radio emission. In the \(<100\) MeV events, protons are mainly accelerated in CME shocks at coronal heights \(>3\) R.

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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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