Two Phases of Particle Acceleration of a Solar Flare Associated with In Situ Energetic Particles

Creators: Wang 王, Meiqi 美祺¹; Chen 陈, Bin 彬¹; Knuth, Trevor²; Cohen, Christina³; Lee, Jeongwoo¹; Wang, Haimin¹; Yu, Sijie¹

1. New Jersey Institute of Technology
2. Goddard Space Flight Center
3. California Institute of Technology

Abstract

How impulsive solar energetic particle (SEP) events are produced by magnetic-reconnection-driven processes during solar flares remains an outstanding question. Here we report a short-duration SEP event associated with an X-class eruptive flare on 2021 July 3, using a combination of remote sensing observations and in situ measurements. The in situ SEPs were recorded by multiple spacecraft including the Parker Solar Probe. The hard X-ray (HXR) light curve exhibits two impulsive periods. The first period is characterized by a single peak with a rapid rise and decay, while the second period features a more gradual HXR light curve with a harder spectrum. Such observation is consistent with in situ measurements: the energetic electrons were first released during the early impulsive phase when the eruption was initiated. The more energetic in situ electrons were released several minutes later during the second period of the impulsive phase when the eruption was well underway. This second period of energetic electron acceleration also coincides with the release of in situ energetic protons and the onset of an interplanetary type III radio burst. We conclude that these multimessenger observations favor a two-phase particle acceleration scenario: the first, less energetic electron population was produced during the initial reconnection that triggers the flare eruption, and the second, more energetic electron population was accelerated in the region above the loop-top below a well-developed, large-scale reconnection current sheet induced by the eruption.

Copyright and License

Original content from this work may be used under the terms of the Creative Commons Attribution 4.0 licence. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.

Acknowledgement

The authors thank Säm Krucker, William Setterberg, and Yixian Zhang for valuable discussions on HXR spectral analysis. This work is primarily funded by NASA HSO Connect grants 80NSSC20K1282 and 80NSSC20K1283 to NJIT (through a subcontract from SAO). M.W. and B.C. receive additional support from NSF SHINE grant AGS-2229338 to NJIT. H.W. is also supported by NASA grant 80NSSC24M0174. The Expanded Owens Valley Solar Array (EOVSA) was designed and built and is now operated by the New Jersey Institute of Technology (NJIT) as a community facility. EOVSA operations are supported by NSF grants AGS-2130832 and NASA grant 80NSSC20K0026 to NJIT. The authors are grateful to the PSP/IS⊙IS, Fermi/GBM, SDO, e-Callisto, WIND, and ACE teams for making their data publicly available.

Facilities

OVRO:SA - Owens Valley Radio Observatory's Solar Array, Fermi - Fermi Gamma-Ray Space Telescope (formerly GLAST), Parker - , WIND - NASA's solar WIND satellite, ACE - Advanced Composition Explorer satellite, SDO - Solar Dynamics Observatory, GOES - Geostationary Operational Environmetal Satellite.

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