The energetic storm particle events of 3 November 2021

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Frontiers in Astronomy and Space Sciences Pub Date : 2023-07-28 DOI:10.3389/fspas.2023.1209479
F. Chiappetta, M. Laurenza, F. Lepreti, S. Benella, G. Consolini, M. F. Marcucci
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Abstract

Observations of energetic particles at interplanetary shocks are important to study acceleration mechanisms and their connection with magnetohydrodynamic turbulence. Energetic storm particle (ESP) events are increases in proton fluxes that occur locally at the passage time of interplanetary shocks. These events are more dangerous when they are superimposed on the solar energetic particles (SEPs) produced by the eruption of flares and/or CME-driven shocks propagating from the corona to the interplanetary space. We considered ESP events occurring in association with SEPs on 3 November 2021. We used proton fluxes provided by Solar Orbiter (located at 0.85 AU) in the energy range of 30 keV–82 MeV, by Wind at energies from 70 keV to 72 MeV, and ACE in the range from 40 keV to 5 MeV (both located at the Lagrangian point L1, close to 1 AU along the Sun-Earth direction). In order to broaden the range of analyzed energies (40 keV - 72 MeV), we combine these data with the proton fluxes from the SOHO spacecraft, also located at L1. We analyzed the ESP event and fitted the proton energy spectra at both locations with several distributions to shed light on the mechanisms leading to the acceleration of energetic particles. We also investigated the turbulent magnetic field fluctuations around the shock. The obtained ESP spectra, best reproduced by the so-called double power law function, the spectral differences at the two locations, and the shock features (quasi-parallel geometry, enhanced downstream turbulence) suggest that diffusive shock acceleration is responsible for acceleration of low energy particles, whereas stochastic acceleration contributes to the (re) acceleration of high energies ones.
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2021年11月3日的高能风暴粒子事件
行星际激波中高能粒子的观测对于研究加速机制及其与磁流体动力学湍流的关系具有重要意义。高能风暴粒子(ESP)事件是在行星际激波通过时局部发生的质子通量增加。当这些事件叠加在耀斑爆发和/或日冕向行星际空间传播的cme驱动的冲击产生的太阳高能粒子(sep)上时,这些事件更加危险。我们考虑了2021年11月3日发生的与sep相关的ESP事件。我们使用的质子通量由太阳轨道器(位于0.85 AU)提供,能量范围为30 keV - 82 MeV,由Wind提供,能量范围为70 keV至72 MeV, ACE提供,能量范围为40 keV至5 MeV(都位于拉格朗日点L1,沿太阳-地球方向接近1 AU)。为了扩大分析的能量范围(40kev - 72mev),我们将这些数据与同样位于L1的SOHO航天器的质子通量相结合。我们分析了ESP事件,并拟合了两个位置的质子能谱与几种分布,以阐明导致高能粒子加速的机制。我们还研究了激波周围的湍流磁场波动。所获得的ESP谱(最好由所谓的双幂律函数再现)、两个位置的谱差异以及激波特征(准平行几何、增强的下游湍流)表明,扩散激波加速度是低能粒子加速的原因,而随机加速度是高能粒子(再)加速的原因。
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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