Energy-Dependent SEP Fe/O Abundances During the May 2024 Superstorm

G. D. Muro; C. M.S. Cohen; Z. Xu; R. A. Leske; A. C. Cummings; S. Bale; G. D. Berland; E. R. Christian; M. E. Cuesta; M. I. Desai; F. Fraschetti; J. Giacalone; L. Y. Khoo; A. Labrador; D. J. McComas; J. G. Mitchell; M. Pulupa; N. A. Schwadron; M. M. Shen

doi:10.1029/2025SW004604

Energy-Dependent SEP Fe/O Abundances During the May 2024 Superstorm

G. D. Muro
, C. M.S. Cohen
, Z. Xu
, R. A. Leske
, A. C. Cummings
, S. Bale
, G. D. Berland
, E. R. Christian
, M. E. Cuesta
, M. I. Desai
, F. Fraschetti
, J. Giacalone
, L. Y. Khoo
, A. Labrador
, D. J. McComas
, J. G. Mitchell
, M. Pulupa
, N. A. Schwadron
, M. M. Shen

Research output: Contribution to journal › Article › peer-review

Abstract

During mid-May 2024, active region (AR) 13664 produced a series of M- and X-class flares along with several coronal mass ejections (CMEs) that resulted in exceptionally strong aurora at Earth. This study presents in situ solar energetic particle (SEP) ion composition data from Solar Terrestrial Relations Observatory Ahead (STA), Advanced Composition Explorer (ACE), and Parker Solar Probe (PSP) as their magnetic connectivity to AR 13664 varied throughout the event period. Between 08 and 24 May, STA was separated by 12° in longitude from ACE at 0.96 AU. SEP intensities rose gradually due to merged CMEs from AR 13664. On 13 May, an M6 flare was followed by a rapid-onset SEP event at STA, although velocity dispersion analysis yielded no clear path length or release time. Parker Solar Probe, 95° longitudinally separated from Earth at 0.74 AU, observed gradually increasing SEP intensities beginning 11 May, followed by a jump in both SEP intensity and magnetic field (>100 nT) on 16 May. These early event intervals display stepwise SEP increases, consistent with the passage of successive CMEs. On 20 May, an X16.5 flare from AR 13664 produced an Fe-rich SEP event observed at all three spacecraft despite their wide longitudinal separations. Throughout the period, Fe/O ratios ranged from <0.01 to >0.8 and increased with energy between 1 and 100 MeV/nuc. This trend deviates from the typical energy-dependent decrease expected from diffusive shock acceleration and suggests more complex scenarios, possibly involving variable suprathermal seed populations or species-dependent transport.

Original language	English (US)
Article number	e2025SW004604
Journal	Space Weather
Volume	23
Issue number	11
DOIs	https://doi.org/10.1029/2025SW004604
State	Published - Nov 2025

Keywords

May 2024
gannon storm
multi-spacecraft
solar energetic particles

ASJC Scopus subject areas

Atmospheric Science

Access to Document

10.1029/2025SW004604

Cite this

Muro, G. D., Cohen, C. M. S., Xu, Z., Leske, R. A., Cummings, A. C., Bale, S., Berland, G. D., Christian, E. R., Cuesta, M. E., Desai, M. I., Fraschetti, F., Giacalone, J., Khoo, L. Y., Labrador, A., McComas, D. J., Mitchell, J. G., Pulupa, M., Schwadron, N. A., & Shen, M. M. (2025). Energy-Dependent SEP Fe/O Abundances During the May 2024 Superstorm. Space Weather, 23(11), Article e2025SW004604. https://doi.org/10.1029/2025SW004604

Muro, GD, Cohen, CMS, Xu, Z, Leske, RA, Cummings, AC, Bale, S, Berland, GD, Christian, ER, Cuesta, ME, Desai, MI, Fraschetti, F, Giacalone, J, Khoo, LY, Labrador, A, McComas, DJ, Mitchell, JG, Pulupa, M, Schwadron, NA & Shen, MM 2025, 'Energy-Dependent SEP Fe/O Abundances During the May 2024 Superstorm', Space Weather, vol. 23, no. 11, e2025SW004604. https://doi.org/10.1029/2025SW004604

@article{3459b1ed542749bc94d1b95aebb39e6e,

title = "Energy-Dependent SEP Fe/O Abundances During the May 2024 Superstorm",

abstract = "During mid-May 2024, active region (AR) 13664 produced a series of M- and X-class flares along with several coronal mass ejections (CMEs) that resulted in exceptionally strong aurora at Earth. This study presents in situ solar energetic particle (SEP) ion composition data from Solar Terrestrial Relations Observatory Ahead (STA), Advanced Composition Explorer (ACE), and Parker Solar Probe (PSP) as their magnetic connectivity to AR 13664 varied throughout the event period. Between 08 and 24 May, STA was separated by 12° in longitude from ACE at 0.96 AU. SEP intensities rose gradually due to merged CMEs from AR 13664. On 13 May, an M6 flare was followed by a rapid-onset SEP event at STA, although velocity dispersion analysis yielded no clear path length or release time. Parker Solar Probe, 95° longitudinally separated from Earth at 0.74 AU, observed gradually increasing SEP intensities beginning 11 May, followed by a jump in both SEP intensity and magnetic field (>100 nT) on 16 May. These early event intervals display stepwise SEP increases, consistent with the passage of successive CMEs. On 20 May, an X16.5 flare from AR 13664 produced an Fe-rich SEP event observed at all three spacecraft despite their wide longitudinal separations. Throughout the period, Fe/O ratios ranged from <0.01 to >0.8 and increased with energy between 1 and 100 MeV/nuc. This trend deviates from the typical energy-dependent decrease expected from diffusive shock acceleration and suggests more complex scenarios, possibly involving variable suprathermal seed populations or species-dependent transport.",

keywords = "May 2024, gannon storm, multi-spacecraft, solar energetic particles",

author = "Muro, \{G. D.\} and Cohen, \{C. M.S.\} and Z. Xu and Leske, \{R. A.\} and Cummings, \{A. C.\} and S. Bale and Berland, \{G. D.\} and Christian, \{E. R.\} and Cuesta, \{M. E.\} and Desai, \{M. I.\} and F. Fraschetti and J. Giacalone and Khoo, \{L. Y.\} and A. Labrador and McComas, \{D. J.\} and Mitchell, \{J. G.\} and M. Pulupa and Schwadron, \{N. A.\} and Shen, \{M. M.\}",

note = "Publisher Copyright: {\textcopyright} 2025. The Author(s).",

year = "2025",

month = nov,

doi = "10.1029/2025SW004604",

language = "English (US)",

volume = "23",

journal = "Space Weather",

issn = "1542-7390",

publisher = "John Wiley and Sons Inc.",

number = "11",

}

TY - JOUR

T1 - Energy-Dependent SEP Fe/O Abundances During the May 2024 Superstorm

AU - Muro, G. D.

AU - Cohen, C. M.S.

AU - Xu, Z.

AU - Leske, R. A.

AU - Cummings, A. C.

AU - Bale, S.

AU - Berland, G. D.

AU - Christian, E. R.

AU - Cuesta, M. E.

AU - Desai, M. I.

AU - Fraschetti, F.

AU - Giacalone, J.

AU - Khoo, L. Y.

AU - Labrador, A.

AU - McComas, D. J.

AU - Mitchell, J. G.

AU - Pulupa, M.

AU - Schwadron, N. A.

AU - Shen, M. M.

PY - 2025/11

Y1 - 2025/11

N2 - During mid-May 2024, active region (AR) 13664 produced a series of M- and X-class flares along with several coronal mass ejections (CMEs) that resulted in exceptionally strong aurora at Earth. This study presents in situ solar energetic particle (SEP) ion composition data from Solar Terrestrial Relations Observatory Ahead (STA), Advanced Composition Explorer (ACE), and Parker Solar Probe (PSP) as their magnetic connectivity to AR 13664 varied throughout the event period. Between 08 and 24 May, STA was separated by 12° in longitude from ACE at 0.96 AU. SEP intensities rose gradually due to merged CMEs from AR 13664. On 13 May, an M6 flare was followed by a rapid-onset SEP event at STA, although velocity dispersion analysis yielded no clear path length or release time. Parker Solar Probe, 95° longitudinally separated from Earth at 0.74 AU, observed gradually increasing SEP intensities beginning 11 May, followed by a jump in both SEP intensity and magnetic field (>100 nT) on 16 May. These early event intervals display stepwise SEP increases, consistent with the passage of successive CMEs. On 20 May, an X16.5 flare from AR 13664 produced an Fe-rich SEP event observed at all three spacecraft despite their wide longitudinal separations. Throughout the period, Fe/O ratios ranged from <0.01 to >0.8 and increased with energy between 1 and 100 MeV/nuc. This trend deviates from the typical energy-dependent decrease expected from diffusive shock acceleration and suggests more complex scenarios, possibly involving variable suprathermal seed populations or species-dependent transport.

AB - During mid-May 2024, active region (AR) 13664 produced a series of M- and X-class flares along with several coronal mass ejections (CMEs) that resulted in exceptionally strong aurora at Earth. This study presents in situ solar energetic particle (SEP) ion composition data from Solar Terrestrial Relations Observatory Ahead (STA), Advanced Composition Explorer (ACE), and Parker Solar Probe (PSP) as their magnetic connectivity to AR 13664 varied throughout the event period. Between 08 and 24 May, STA was separated by 12° in longitude from ACE at 0.96 AU. SEP intensities rose gradually due to merged CMEs from AR 13664. On 13 May, an M6 flare was followed by a rapid-onset SEP event at STA, although velocity dispersion analysis yielded no clear path length or release time. Parker Solar Probe, 95° longitudinally separated from Earth at 0.74 AU, observed gradually increasing SEP intensities beginning 11 May, followed by a jump in both SEP intensity and magnetic field (>100 nT) on 16 May. These early event intervals display stepwise SEP increases, consistent with the passage of successive CMEs. On 20 May, an X16.5 flare from AR 13664 produced an Fe-rich SEP event observed at all three spacecraft despite their wide longitudinal separations. Throughout the period, Fe/O ratios ranged from <0.01 to >0.8 and increased with energy between 1 and 100 MeV/nuc. This trend deviates from the typical energy-dependent decrease expected from diffusive shock acceleration and suggests more complex scenarios, possibly involving variable suprathermal seed populations or species-dependent transport.

KW - May 2024

KW - gannon storm

KW - multi-spacecraft

KW - solar energetic particles

UR - https://www.scopus.com/pages/publications/105021950847

UR - https://www.scopus.com/pages/publications/105021950847#tab=citedBy

U2 - 10.1029/2025SW004604

DO - 10.1029/2025SW004604

M3 - Article

AN - SCOPUS:105021950847

SN - 1542-7390

VL - 23

JO - Space Weather

JF - Space Weather

IS - 11

M1 - e2025SW004604

ER -

Energy-Dependent SEP Fe/O Abundances During the May 2024 Superstorm

Abstract

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this