CME Magnetic Structure and IMF Preconditioning Affecting SEP Transport

Erika Palmerio; Emilia K.J. Kilpua; Olivier Witasse; David Barnes; Beatriz Sánchez-Cano; Andreas J. Weiss; Teresa Nieves-Chinchilla; Christian Möstl; Lan K. Jian; Marilena Mierla; Andrei N. Zhukov; Jingnan Guo; Luciano Rodriguez; Patrick J. Lowrance; Alexey Isavnin; Lucile Turc; Yoshifumi Futaana; Mats Holmström

doi:10.1029/2020SW002654

CME Magnetic Structure and IMF Preconditioning Affecting SEP Transport

Erika Palmerio^*, Emilia K.J. Kilpua, Olivier Witasse, David Barnes, Beatriz Sánchez-Cano, Andreas J. Weiss, Teresa Nieves-Chinchilla, Christian Möstl, Lan K. Jian, Marilena Mierla, Andrei N. Zhukov, Jingnan Guo, Luciano Rodriguez, Patrick J. Lowrance, Alexey Isavnin, Lucile Turc, Yoshifumi Futaana, Mats Holmström

^*Corresponding author for this work

Institute of Geodesy (5220)

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

Abstract

Coronal mass ejections (CMEs) and solar energetic particles (SEPs) are two phenomena that can cause severe space weather effects throughout the heliosphere. The evolution of CMEs, especially in terms of their magnetic structure, and the configuration of the interplanetary magnetic field (IMF) that influences the transport of SEPs are currently areas of active research. These two aspects are not necessarily independent of each other, especially during solar maximum when multiple eruptive events can occur close in time. Accordingly, we present the analysis of a CME that erupted on May 11, 2012 (SOL2012-05-11) and an SEP event following an eruption that took place on May 17, 2012 (SOL2012-05-17). After observing the May 11 CME using remote-sensing data from three viewpoints, we evaluate its propagation through interplanetary space using several models. Then, we analyze in-situ measurements from five predicted impact locations (Venus, Earth, the Spitzer Space Telescope, the Mars Science Laboratory en route to Mars, and Mars) in order to search for CME signatures. We find that all in-situ locations detect signatures of an SEP event, which we trace back to the May 17 eruption. These findings suggest that the May 11 CME provided a direct magnetic connectivity for the efficient transport of SEPs. We discuss the space weather implications of CME evolution, regarding in particular its magnetic structure, and CME-driven IMF preconditioning that facilitates SEP transport. Finally, this work remarks the importance of using data from multiple spacecraft, even those that do not include space weather research as their primary objective.

Original language	English
Article number	e2020SW002654
Journal	Space Weather
Volume	19
Issue number	4
DOIs	https://doi.org/10.1029/2020SW002654
Publication status	Published - Apr 2021

Keywords

coronal mass ejections
heliophysics
interplanetary magnetic field
solar energetic particles
solar wind
space weather

ASJC Scopus subject areas

Atmospheric Science

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10.1029/2020SW002654Licence: CC BY 4.0

Cite this

Palmerio, E., Kilpua, E. K. J., Witasse, O., Barnes, D., Sánchez-Cano, B., Weiss, A. J., Nieves-Chinchilla, T., Möstl, C., Jian, L. K., Mierla, M., Zhukov, A. N., Guo, J., Rodriguez, L., Lowrance, P. J., Isavnin, A., Turc, L., Futaana, Y., & Holmström, M. (2021). CME Magnetic Structure and IMF Preconditioning Affecting SEP Transport. Space Weather, 19(4), [e2020SW002654]. https://doi.org/10.1029/2020SW002654

Palmerio, E, Kilpua, EKJ, Witasse, O, Barnes, D, Sánchez-Cano, B, Weiss, AJ, Nieves-Chinchilla, T, Möstl, C, Jian, LK, Mierla, M, Zhukov, AN, Guo, J, Rodriguez, L, Lowrance, PJ, Isavnin, A, Turc, L, Futaana, Y & Holmström, M 2021, 'CME Magnetic Structure and IMF Preconditioning Affecting SEP Transport', Space Weather, vol. 19, no. 4, e2020SW002654. https://doi.org/10.1029/2020SW002654

@article{c27557d40e15456ebf66eac68597f313,

title = "CME Magnetic Structure and IMF Preconditioning Affecting SEP Transport",

abstract = "Coronal mass ejections (CMEs) and solar energetic particles (SEPs) are two phenomena that can cause severe space weather effects throughout the heliosphere. The evolution of CMEs, especially in terms of their magnetic structure, and the configuration of the interplanetary magnetic field (IMF) that influences the transport of SEPs are currently areas of active research. These two aspects are not necessarily independent of each other, especially during solar maximum when multiple eruptive events can occur close in time. Accordingly, we present the analysis of a CME that erupted on May 11, 2012 (SOL2012-05-11) and an SEP event following an eruption that took place on May 17, 2012 (SOL2012-05-17). After observing the May 11 CME using remote-sensing data from three viewpoints, we evaluate its propagation through interplanetary space using several models. Then, we analyze in-situ measurements from five predicted impact locations (Venus, Earth, the Spitzer Space Telescope, the Mars Science Laboratory en route to Mars, and Mars) in order to search for CME signatures. We find that all in-situ locations detect signatures of an SEP event, which we trace back to the May 17 eruption. These findings suggest that the May 11 CME provided a direct magnetic connectivity for the efficient transport of SEPs. We discuss the space weather implications of CME evolution, regarding in particular its magnetic structure, and CME-driven IMF preconditioning that facilitates SEP transport. Finally, this work remarks the importance of using data from multiple spacecraft, even those that do not include space weather research as their primary objective.",

keywords = "coronal mass ejections, heliophysics, interplanetary magnetic field, solar energetic particles, solar wind, space weather",

author = "Erika Palmerio and Kilpua, {Emilia K.J.} and Olivier Witasse and David Barnes and Beatriz S{\'a}nchez-Cano and Weiss, {Andreas J.} and Teresa Nieves-Chinchilla and Christian M{\"o}stl and Jian, {Lan K.} and Marilena Mierla and Zhukov, {Andrei N.} and Jingnan Guo and Luciano Rodriguez and Lowrance, {Patrick J.} and Alexey Isavnin and Lucile Turc and Yoshifumi Futaana and Mats Holmstr{\"o}m",

note = "Funding Information: E. Palmerio acknowledges the Doctoral Programme in Particle Physics and Universe Sciences (PAPU) at the University of Helsinki, the Emil Aaltonen Foundation, and the NASA Living With a Star Jack Eddy Postdoctoral Fellowship Program, administered by UCAR's Cooperative Programs for the Advancement of Earth System Science (CPAESS) under award no. NNX16AK22G. E. Kilpua acknowledges the SolMAG project (ERC-COG 724391) funded by the European Research Council (ERC) in the framework of the Horizon 2020 Research and Innovation Programme, Academy of Finland project SMASH (grant no. 310445), and the Finnish Centre of Excellence in Research of Sustainable Space (Academy of Finland grant no. 312390). B. S?nchez-Cano acknowledges support through UK-STFC grant ST/S000429/1. A. Weiss and C. M?stl thank the Austrian Science Fund (FWF): P31521-N27. M. Mierla, A. Zhukov, and L. Rodriguez thank the European Space Agency (ESA) and the Belgian Federal Science Policy Office (BELSPO) for their support in the framework of the PRODEX Programme. J. Guo thanks the Strategic Priority Program of the Chinese Academy of Sciences (grant no. XDB41000000 and XDA15017300), and the CNSA preresearch Project on Civil Aerospace Technologies (grant no. D020104). The work of L. Turc is supported by the Academy of Finland (grant no. 322544). We thank two anonymous reviewers, whose comments and suggestions have significantly improved this article. We acknowledge support from the European Union FP7-SPACE-2013-1 programme for the HELCATS project (grant no. 606692). The HI instruments on STEREO were developed by a consortium that comprised the Rutherford Appleton Laboratory (UK), the University of Birmingham (UK), Centre Spatial de Li?ge (CSL, Belgium) and the Naval Research Laboratory (NRL, USA). The STEREO/SECCHI project, of which HI is a part, is an international consortium led by NRL. We recognize the support of the UK Space Agency for funding STEREO/HI operations in the UK. The WSA model was developed by C. N. Arge (currently at NASA/GSFC), and the Enlil model was developed by D. Odstrcil (currently at GMU). We thank the model developers, M. L. Mays, R. Colaninno, and the CCMC staff. We acknowledge the NMDB, founded under the European Union's FP7 programme (contract no. 213007), for providing neutron monitor data. We thank the WDC for Geomagnetism, Kyoto, and the geomagnetic observatories for their cooperation to make the final Dst indices available. This work is based (in part) on archival data obtained with the Spitzer Space Telescope, which was operated by the Jet Propulsion Laboratory, California Institute of Technology, under a contract with NASA. Support for this work was provided by an award issued by JPL/Caltech. Finally, we thank the instrument teams of all the spacecraft involved in this study. Funding Information: E. Palmerio acknowledges the Doctoral Programme in Particle Physics and Universe Sciences (PAPU) at the University of Helsinki, the Emil Aaltonen Foundation, and the NASA Living With a Star Jack Eddy Postdoctoral Fellowship Program, administered by UCAR's Cooperative Programs for the Advancement of Earth System Science (CPAESS) under award no. NNX16AK22G. E. Kilpua acknowledges the SolMAG project (ERC‐COG 724391) funded by the European Research Council (ERC) in the framework of the Horizon 2020 Research and Innovation Programme, Academy of Finland project SMASH (grant no. 310445), and the Finnish Centre of Excellence in Research of Sustainable Space (Academy of Finland grant no. 312390). B. S{\'a}nchez‐Cano acknowledges support through UK‐STFC grant ST/S000429/1. A. Weiss and C. M{\"o}stl thank the Austrian Science Fund (FWF): P31521‐N27. M. Mierla, A. Zhukov, and L. Rodriguez thank the European Space Agency (ESA) and the Belgian Federal Science Policy Office (BELSPO) for their support in the framework of the PRODEX Programme. J. Guo thanks the Strategic Priority Program of the Chinese Academy of Sciences (grant no. XDB41000000 and XDA15017300), and the CNSA preresearch Project on Civil Aerospace Technologies (grant no. D020104). The work of L. Turc is supported by the Academy of Finland (grant no. 322544). We thank two anonymous reviewers, whose comments and suggestions have significantly improved this article. We acknowledge support from the European Union FP7‐SPACE‐2013‐1 programme for the HELCATS project (grant no. 606692). The HI instruments on STEREO were developed by a consortium that comprised the Rutherford Appleton Laboratory (UK), the University of Birmingham (UK), Centre Spatial de Li{\`e}ge (CSL, Belgium) and the Naval Research Laboratory (NRL, USA). The STEREO/SECCHI project, of which HI is a part, is an international consortium led by NRL. We recognize the support of the UK Space Agency for funding STEREO/HI operations in the UK. The WSA model was developed by C. N. Arge (currently at NASA/GSFC), and the Enlil model was developed by D. Odstrcil (currently at GMU). We thank the model developers, M. L. Mays, R. Colaninno, and the CCMC staff. We acknowledge the NMDB, founded under the European Union's FP7 programme (contract no. 213007), for providing neutron monitor data. We thank the WDC for Geomagnetism, Kyoto, and the geomagnetic observatories for their cooperation to make the final Dst indices available. This work is based (in part) on archival data obtained with the Spitzer Space Telescope, which was operated by the Jet Propulsion Laboratory, California Institute of Technology, under a contract with NASA. Support for this work was provided by an award issued by JPL/Caltech. Finally, we thank the instrument teams of all the spacecraft involved in this study. Publisher Copyright: {\textcopyright} 2021. The Authors.",

year = "2021",

month = apr,

doi = "10.1029/2020SW002654",

language = "English",

volume = "19",

journal = "Space Weather",

issn = "1542-7390",

publisher = "American Geophysical Union",

number = "4",

}

TY - JOUR

T1 - CME Magnetic Structure and IMF Preconditioning Affecting SEP Transport

AU - Palmerio, Erika

AU - Kilpua, Emilia K.J.

AU - Witasse, Olivier

AU - Barnes, David

AU - Sánchez-Cano, Beatriz

AU - Weiss, Andreas J.

AU - Nieves-Chinchilla, Teresa

AU - Möstl, Christian

AU - Jian, Lan K.

AU - Mierla, Marilena

AU - Zhukov, Andrei N.

AU - Guo, Jingnan

AU - Rodriguez, Luciano

AU - Lowrance, Patrick J.

AU - Isavnin, Alexey

AU - Turc, Lucile

AU - Futaana, Yoshifumi

AU - Holmström, Mats

N1 - Funding Information: E. Palmerio acknowledges the Doctoral Programme in Particle Physics and Universe Sciences (PAPU) at the University of Helsinki, the Emil Aaltonen Foundation, and the NASA Living With a Star Jack Eddy Postdoctoral Fellowship Program, administered by UCAR's Cooperative Programs for the Advancement of Earth System Science (CPAESS) under award no. NNX16AK22G. E. Kilpua acknowledges the SolMAG project (ERC-COG 724391) funded by the European Research Council (ERC) in the framework of the Horizon 2020 Research and Innovation Programme, Academy of Finland project SMASH (grant no. 310445), and the Finnish Centre of Excellence in Research of Sustainable Space (Academy of Finland grant no. 312390). B. S?nchez-Cano acknowledges support through UK-STFC grant ST/S000429/1. A. Weiss and C. M?stl thank the Austrian Science Fund (FWF): P31521-N27. M. Mierla, A. Zhukov, and L. Rodriguez thank the European Space Agency (ESA) and the Belgian Federal Science Policy Office (BELSPO) for their support in the framework of the PRODEX Programme. J. Guo thanks the Strategic Priority Program of the Chinese Academy of Sciences (grant no. XDB41000000 and XDA15017300), and the CNSA preresearch Project on Civil Aerospace Technologies (grant no. D020104). The work of L. Turc is supported by the Academy of Finland (grant no. 322544). We thank two anonymous reviewers, whose comments and suggestions have significantly improved this article. We acknowledge support from the European Union FP7-SPACE-2013-1 programme for the HELCATS project (grant no. 606692). The HI instruments on STEREO were developed by a consortium that comprised the Rutherford Appleton Laboratory (UK), the University of Birmingham (UK), Centre Spatial de Li?ge (CSL, Belgium) and the Naval Research Laboratory (NRL, USA). The STEREO/SECCHI project, of which HI is a part, is an international consortium led by NRL. We recognize the support of the UK Space Agency for funding STEREO/HI operations in the UK. The WSA model was developed by C. N. Arge (currently at NASA/GSFC), and the Enlil model was developed by D. Odstrcil (currently at GMU). We thank the model developers, M. L. Mays, R. Colaninno, and the CCMC staff. We acknowledge the NMDB, founded under the European Union's FP7 programme (contract no. 213007), for providing neutron monitor data. We thank the WDC for Geomagnetism, Kyoto, and the geomagnetic observatories for their cooperation to make the final Dst indices available. This work is based (in part) on archival data obtained with the Spitzer Space Telescope, which was operated by the Jet Propulsion Laboratory, California Institute of Technology, under a contract with NASA. Support for this work was provided by an award issued by JPL/Caltech. Finally, we thank the instrument teams of all the spacecraft involved in this study. Funding Information: E. Palmerio acknowledges the Doctoral Programme in Particle Physics and Universe Sciences (PAPU) at the University of Helsinki, the Emil Aaltonen Foundation, and the NASA Living With a Star Jack Eddy Postdoctoral Fellowship Program, administered by UCAR's Cooperative Programs for the Advancement of Earth System Science (CPAESS) under award no. NNX16AK22G. E. Kilpua acknowledges the SolMAG project (ERC‐COG 724391) funded by the European Research Council (ERC) in the framework of the Horizon 2020 Research and Innovation Programme, Academy of Finland project SMASH (grant no. 310445), and the Finnish Centre of Excellence in Research of Sustainable Space (Academy of Finland grant no. 312390). B. Sánchez‐Cano acknowledges support through UK‐STFC grant ST/S000429/1. A. Weiss and C. Möstl thank the Austrian Science Fund (FWF): P31521‐N27. M. Mierla, A. Zhukov, and L. Rodriguez thank the European Space Agency (ESA) and the Belgian Federal Science Policy Office (BELSPO) for their support in the framework of the PRODEX Programme. J. Guo thanks the Strategic Priority Program of the Chinese Academy of Sciences (grant no. XDB41000000 and XDA15017300), and the CNSA preresearch Project on Civil Aerospace Technologies (grant no. D020104). The work of L. Turc is supported by the Academy of Finland (grant no. 322544). We thank two anonymous reviewers, whose comments and suggestions have significantly improved this article. We acknowledge support from the European Union FP7‐SPACE‐2013‐1 programme for the HELCATS project (grant no. 606692). The HI instruments on STEREO were developed by a consortium that comprised the Rutherford Appleton Laboratory (UK), the University of Birmingham (UK), Centre Spatial de Liège (CSL, Belgium) and the Naval Research Laboratory (NRL, USA). The STEREO/SECCHI project, of which HI is a part, is an international consortium led by NRL. We recognize the support of the UK Space Agency for funding STEREO/HI operations in the UK. The WSA model was developed by C. N. Arge (currently at NASA/GSFC), and the Enlil model was developed by D. Odstrcil (currently at GMU). We thank the model developers, M. L. Mays, R. Colaninno, and the CCMC staff. We acknowledge the NMDB, founded under the European Union's FP7 programme (contract no. 213007), for providing neutron monitor data. We thank the WDC for Geomagnetism, Kyoto, and the geomagnetic observatories for their cooperation to make the final Dst indices available. This work is based (in part) on archival data obtained with the Spitzer Space Telescope, which was operated by the Jet Propulsion Laboratory, California Institute of Technology, under a contract with NASA. Support for this work was provided by an award issued by JPL/Caltech. Finally, we thank the instrument teams of all the spacecraft involved in this study. Publisher Copyright: © 2021. The Authors.

PY - 2021/4

Y1 - 2021/4

N2 - Coronal mass ejections (CMEs) and solar energetic particles (SEPs) are two phenomena that can cause severe space weather effects throughout the heliosphere. The evolution of CMEs, especially in terms of their magnetic structure, and the configuration of the interplanetary magnetic field (IMF) that influences the transport of SEPs are currently areas of active research. These two aspects are not necessarily independent of each other, especially during solar maximum when multiple eruptive events can occur close in time. Accordingly, we present the analysis of a CME that erupted on May 11, 2012 (SOL2012-05-11) and an SEP event following an eruption that took place on May 17, 2012 (SOL2012-05-17). After observing the May 11 CME using remote-sensing data from three viewpoints, we evaluate its propagation through interplanetary space using several models. Then, we analyze in-situ measurements from five predicted impact locations (Venus, Earth, the Spitzer Space Telescope, the Mars Science Laboratory en route to Mars, and Mars) in order to search for CME signatures. We find that all in-situ locations detect signatures of an SEP event, which we trace back to the May 17 eruption. These findings suggest that the May 11 CME provided a direct magnetic connectivity for the efficient transport of SEPs. We discuss the space weather implications of CME evolution, regarding in particular its magnetic structure, and CME-driven IMF preconditioning that facilitates SEP transport. Finally, this work remarks the importance of using data from multiple spacecraft, even those that do not include space weather research as their primary objective.

AB - Coronal mass ejections (CMEs) and solar energetic particles (SEPs) are two phenomena that can cause severe space weather effects throughout the heliosphere. The evolution of CMEs, especially in terms of their magnetic structure, and the configuration of the interplanetary magnetic field (IMF) that influences the transport of SEPs are currently areas of active research. These two aspects are not necessarily independent of each other, especially during solar maximum when multiple eruptive events can occur close in time. Accordingly, we present the analysis of a CME that erupted on May 11, 2012 (SOL2012-05-11) and an SEP event following an eruption that took place on May 17, 2012 (SOL2012-05-17). After observing the May 11 CME using remote-sensing data from three viewpoints, we evaluate its propagation through interplanetary space using several models. Then, we analyze in-situ measurements from five predicted impact locations (Venus, Earth, the Spitzer Space Telescope, the Mars Science Laboratory en route to Mars, and Mars) in order to search for CME signatures. We find that all in-situ locations detect signatures of an SEP event, which we trace back to the May 17 eruption. These findings suggest that the May 11 CME provided a direct magnetic connectivity for the efficient transport of SEPs. We discuss the space weather implications of CME evolution, regarding in particular its magnetic structure, and CME-driven IMF preconditioning that facilitates SEP transport. Finally, this work remarks the importance of using data from multiple spacecraft, even those that do not include space weather research as their primary objective.

KW - coronal mass ejections

KW - heliophysics

KW - interplanetary magnetic field

KW - solar energetic particles

KW - solar wind

KW - space weather

UR - http://www.scopus.com/inward/record.url?scp=85105004492&partnerID=8YFLogxK

U2 - 10.1029/2020SW002654

DO - 10.1029/2020SW002654

M3 - Article

AN - SCOPUS:85105004492

VL - 19

JO - Space Weather

JF - Space Weather

SN - 1542-7390

IS - 4

M1 - e2020SW002654

ER -

CME Magnetic Structure and IMF Preconditioning Affecting SEP Transport

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