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Main Authors: Walker, Malik H., Allen, Robert C., Ho, George C., Mason, Glenn M., Cohen, Christina M. S., Lee, Christina, Möstl, Christian, Davies, Emma E., Weiler, Eva
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.00163
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author Walker, Malik H.
Allen, Robert C.
Ho, George C.
Mason, Glenn M.
Cohen, Christina M. S.
Lee, Christina
Möstl, Christian
Davies, Emma E.
Weiler, Eva
author_facet Walker, Malik H.
Allen, Robert C.
Ho, George C.
Mason, Glenn M.
Cohen, Christina M. S.
Lee, Christina
Möstl, Christian
Davies, Emma E.
Weiler, Eva
contents During the propagation of interplanetary coronal mass ejections (ICMEs), evolution of the ICME-driven shock along with interactions with other solar wind structures, planetary bodies, and general changes to their morphology can alter particle acceleration efficiency and transport effects at their associated shocks. While the underlying mechanisms for these processes have been studied, the connection between the radial evolution of the ICME-driven shock during propagation and resulting gradual Solar Energetic Particle (SEP)and Energetic Storm Particle (ESP) intensities, composition, and acceleration has yet to be fully understood. The current distributed array of spacecraft at varying heliocentric distances provides a welcome opportunity to statistically analyze the radial dependency of particle populations and acceleration mechanisms present at ICME-driven shocks. We compile a database of 39 multipoint ICME events from 2016-2023, which are observed in situ by at least two of the following spacecraft: Parker Solar Probe (PSP), Solar Orbiter, ACE, Wind, and STEREO-A. Using the magnetic field, plasma, and ion compositional data provided by these spacecraft, we derive both local shock and ESP spectral shape parameters. By comparing the changes in these parameters at different stages of ICME propagation, we analyze the connection between the evolution of the local shock conditions and the spectral shape. We find evidence to suggest a consistent increase in shock acceleration efficiency with heliocentric distance while the parent ICME is within 0.7 au, followed by a reduction in shock efficiency at further distances.
format Preprint
id arxiv_https___arxiv_org_abs_2605_00163
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Radial Dependency of ICME-associated Particle Acceleration Processes: Statistical Multipoint Observations from 2016-2023
Walker, Malik H.
Allen, Robert C.
Ho, George C.
Mason, Glenn M.
Cohen, Christina M. S.
Lee, Christina
Möstl, Christian
Davies, Emma E.
Weiler, Eva
Space Physics
Solar and Stellar Astrophysics
During the propagation of interplanetary coronal mass ejections (ICMEs), evolution of the ICME-driven shock along with interactions with other solar wind structures, planetary bodies, and general changes to their morphology can alter particle acceleration efficiency and transport effects at their associated shocks. While the underlying mechanisms for these processes have been studied, the connection between the radial evolution of the ICME-driven shock during propagation and resulting gradual Solar Energetic Particle (SEP)and Energetic Storm Particle (ESP) intensities, composition, and acceleration has yet to be fully understood. The current distributed array of spacecraft at varying heliocentric distances provides a welcome opportunity to statistically analyze the radial dependency of particle populations and acceleration mechanisms present at ICME-driven shocks. We compile a database of 39 multipoint ICME events from 2016-2023, which are observed in situ by at least two of the following spacecraft: Parker Solar Probe (PSP), Solar Orbiter, ACE, Wind, and STEREO-A. Using the magnetic field, plasma, and ion compositional data provided by these spacecraft, we derive both local shock and ESP spectral shape parameters. By comparing the changes in these parameters at different stages of ICME propagation, we analyze the connection between the evolution of the local shock conditions and the spectral shape. We find evidence to suggest a consistent increase in shock acceleration efficiency with heliocentric distance while the parent ICME is within 0.7 au, followed by a reduction in shock efficiency at further distances.
title Radial Dependency of ICME-associated Particle Acceleration Processes: Statistical Multipoint Observations from 2016-2023
topic Space Physics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2605.00163