Revisiting Empirical Solar Energetic Particle Scaling Relations II. Coronal Mass Ejections

arXiv - PHYS - Space Physics Pub Date : 2024-07-23 DOI:arxiv-2407.16479

Athanasios Papaioannou, Konstantin Herbst, Tobias Ramm, David Lario, Astrid M. Veronig

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Abstract

Aims. The space radiation environment conditions and the maximum expected coronal mass ejection (CME) speed are being assessed through the investigation of scaling laws between the peak proton flux and fluence of Solar Energetic Particle (SEP) events with the speed of the CMEs. Methods. We utilize a complete catalog of SEP events, covering the last ~25 years of CME observations (i.e. 1997 to 2017). We calculate the peak proton fluxes and integrated event fluences for those events reaching an integral energy of up to E> 100 MeV, covering the period of the last ~25 years of CME observations. For a sample of 38 strong SEP events, we first investigate the statistical relations between the recorded peak proton fluxes (IP) and fluences (FP) at a set of integral energies of E >10 MeV, E>30 MeV, E>60 MeV, and E>100 MeV versus the projected CME speed near the Sun (VCME) obtained by the Solar and Heliospheric Observatory/Large Angle and Spectrometric Coronagraph (SOHO/LASCO). Based on the inferred relations, we further calculate the integrated energy dependence of both IP and FP, assuming that they follow an inverse power-law with respect to energy. By making use of simple physical assumptions, we combine our derived scaling laws to estimate the upper limits for VCME, IP, and FP focusing on two cases of known extreme SEP events that occurred on February 23, 1956 (GLE05) and in AD774/775, respectively. Given physical constraints and assumptions, several options for the upper limit VCME, associated with these events, are investigated. Results. A scaling law relating IP and FP to the CME speed as V^{5}CME for CMEs ranging between ~3400-5400 km/s is consistent with values of FP inferred for the cosmogenic nuclide event of AD774/775. At the same time, the upper CME speed that the current Sun can provide possibly falls within an upper limit of VCME <= 5500 km/s.

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重新审视经验太阳能量粒子比例关系 II.日冕物质抛射

目的。通过研究太阳高能粒子（SEP）事件的质子峰值通量和通量与 CME 速度之间的比例关系，评估空间辐射环境条件和预期的最大日冕物质抛射（CME）速度。方法。我们利用了一份完整的SEP事件目录，涵盖了过去约25年的CME观测（即1997年至2017年）。我们计算了那些积分能量达到 E> 100 MeV 的事件的质子峰值通量和事件综合影响，涵盖了过去约 25 年的 CME 观测。对于 38 个强 SEP 事件样本，我们首先研究了在一组积分能量 E >10 MeV、E >30 MeV、E >60 MeV 和 E >100 MeV 下记录的峰值质子通量（IP）和通量（FP）与太阳和日光层观测站/大角度和分光日冕仪（SOHO/LASCO）获得的近太阳 CME 预测速度（VCME）之间的统计关系。在推断关系的基础上，我们进一步计算了 IP 和 FP 的综合能量依赖性，假定它们遵循与能量有关的反幂律。通过利用简单的物理假设，我们结合推导出的缩放定律，估算了 VCME、IP 和 FP 的上限，重点是两个已知的极端 SEP 事件，分别发生在 1956 年 2 月 23 日（GLE05）和公元 774/775 年。考虑到物理限制和假设，研究了与这些事件相关的 VCME 上限的几种选择。结果。IP和FP与CME速度的比例关系为V^{5}CME，CME的速度范围为~3400-5400千米/秒，这与AD774/775宇宙成因核素事件推断的FP值一致。同时，目前太阳所能提供的CME速度上限可能在VCME <= 5500 km/s的上限之内。

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arXiv - PHYS - Space Physics

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