Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer

A. Masters; R. Modolo; E. Roussos; N. Krupp; O. Witasse; C. Vallat; B. Cecconi; N. J.T. Edberg; Y. Futaana; M. Galand; D. Heyner; M. Holmberg; H. Huybrighs; X. Jia; K. Khurana; L. Lamy; L. Roth; A. Sulaiman; P. Tortora; S. Barabash; L. Bruzzone; M. K. Dougherty; R. Gladstone; L. I. Gurvits; P. Hartogh; H. Hussmann; L. Iess; F. Poulet; J. E. Wahlund; D. J. Andrews; C. S. Arridge; F. Bagenal; C. Baskevitch; J. Bergman; T. M. Bocanegra; P. Brandt; E. J. Bunce; G. Clark; A. J. Coates; E. Galanti; A. Galli; D. Grodent; G. Jones; Y. Kasaba; Y. Kaspi; Y. Katoh; N. Kaweeyanun; Y. Khotyaintsev; T. Kimura; P. Kollmann; D. Mitchell; A. Moirano; G. Molera Calvés; M. Morooka; I. C.F. Müller-Wodarg; C. Muñoz; A. Mura; M. Pätzold; M. Pinto; C. Plainaki; K. D. Retherford; A. Retinò; H. Rothkaehl; O. Santolík; J. Saur; G. Stenberg Wieser; F. Tsuchiya; M. Volwerk; A. Vorburger; P. Wurz; M. Zannoni

doi:10.1007/s11214-025-01148-8

Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer

A. Masters
, R. Modolo
, E. Roussos
, N. Krupp
, O. Witasse
, C. Vallat
, B. Cecconi
, N. J.T. Edberg
, Y. Futaana
, M. Galand
, D. Heyner
, M. Holmberg
, H. Huybrighs
, X. Jia
, K. Khurana
, L. Lamy
, L. Roth
, A. Sulaiman
, P. Tortora
, S. Barabash

L. Bruzzone, M. K. Dougherty, R. Gladstone, L. I. Gurvits, P. Hartogh, H. Hussmann, L. Iess, F. Poulet, J. E. Wahlund, D. J. Andrews, C. S. Arridge, F. Bagenal, C. Baskevitch, J. Bergman, T. M. Bocanegra, P. Brandt, E. J. Bunce, G. Clark, A. J. Coates, E. Galanti, A. Galli, D. Grodent, G. Jones, Y. Kasaba, Y. Kaspi, Y. Katoh, N. Kaweeyanun, Y. Khotyaintsev, T. Kimura, P. Kollmann, D. Mitchell, A. Moirano, G. Molera Calvés, M. Morooka, I. C.F. Müller-Wodarg, C. Muñoz, A. Mura, M. Pätzold, M. Pinto, C. Plainaki, K. D. Retherford, A. Retinò, H. Rothkaehl, O. Santolík, J. Saur, G. Stenberg Wieser, F. Tsuchiya, M. Volwerk, A. Vorburger, P. Wurz, M. Zannoni

Imperial College London
Université Versailles-Saint Quentin
Max-Planck-Institut für Sonnensystemforschung
ESTEC - European Space Research and Technology Centre
ESAC campus
LESIA - Laboratoire d'Etudes Spatiales et d'Instrumentation en Astrophysique
Swedish Institute of Space Physics
Technical University Braunschweig
Dublin Institute for Advanced Studies
Khalifa University of Sciences and Technology
University of Michigan
University of California, Los Angeles
LAM
KTH Royal Institute of Technology
University of Minnesota
University of Bologna
Università di Trento
Southwest Research Institute
University of Texas
Joint Institute for VLBI ERIC
Delft University of Technology
DLR
University of Rome
Institut d'Astrophysique Spatiale
Lancaster University
University of Colorado Boulder
California Institute of Technology
Johns Hopkins University Applied Physics Laboratory
University of Leicester
UCL Mullard Space Science Laboratory
Centre for Planetary Sciences at UCL/Birkbeck
Weizmann Institute of Science Israel
University of Bern, Institute of Applied Physics
University of Liège
Tohoku University
University of Southampton
Tokyo University of Science
Istituto di Astrofisica e Planetologia Spaziali (IAPS)
University of Tasmania
Rheinisches Institut fuer Umweltforschung
Science and Research Directorate
Polish Academy of Sciences
Institute of Atmospheric Physics of the Academy of Sciences of the Czech Republic
Charles University
Germany; University of Cologne
Space Research Institute

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

Abstract

The Jupiter Icy Moons Explorer (JUICE) is a European Space Agency mission to explore Jupiter and its three icy Galilean moons: Europa, Ganymede, and Callisto. Numerous JUICE investigations concern the magnetised space environments containing low-density populations of charged particles that surround each of these bodies. In the case of both Jupiter and Ganymede, the magnetic field generated internally produces a surrounding volume of space known as a magnetosphere. All these regions are natural laboratories where we can test and further our understanding of how such systems work, and improved knowledge of the environments around the moons of interest is important for probing sub-surface oceans that may be habitable. Here we review the magnetosphere and plasma science that will be enabled by JUICE from arrival at Jupiter in July 2031. We focus on the specific topics where the mission will push forward the boundaries of our understanding through a combination of the spacecraft trajectory through the system and the measurements that will be made by its suite of scientific instruments. Advances during the initial orbits around Jupiter will include construction of a comprehensive picture of the poorly understood region of Jupiter’s magnetosphere where rigid plasma rotation with the planet breaks down, and new perspectives on how Jupiter’s magnetosphere interacts with both Europa and Callisto. The later orbits around Ganymede will dramatically improve knowledge of this moon’s smaller magnetosphere embedded within the larger magnetosphere of Jupiter. We conclude by outlining the high-level operational strategy that will support this broad science return.

Original language	English
Article number	24
Journal	Space Science Reviews
Volume	221
Issue number	2
DOIs	https://doi.org/10.1007/s11214-025-01148-8
Publication status	Published - 1 Mar 2025

Keywords

Callisto
Europa
Ganymede
Jupiter
Magnetospheres
Space plasmas

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10.1007/s11214-025-01148-8

Cite this

Masters, A., Modolo, R., Roussos, E., Krupp, N., Witasse, O., Vallat, C., Cecconi, B., Edberg, N. J. T., Futaana, Y., Galand, M., Heyner, D., Holmberg, M., Huybrighs, H., Jia, X., Khurana, K., Lamy, L., Roth, L., Sulaiman, A., Tortora, P., ... Zannoni, M. (2025). Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer. Space Science Reviews, 221(2), Article 24. https://doi.org/10.1007/s11214-025-01148-8

@article{d54971fbcf32478fa78cfd4c215c78ed,

title = "Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer",

abstract = "The Jupiter Icy Moons Explorer (JUICE) is a European Space Agency mission to explore Jupiter and its three icy Galilean moons: Europa, Ganymede, and Callisto. Numerous JUICE investigations concern the magnetised space environments containing low-density populations of charged particles that surround each of these bodies. In the case of both Jupiter and Ganymede, the magnetic field generated internally produces a surrounding volume of space known as a magnetosphere. All these regions are natural laboratories where we can test and further our understanding of how such systems work, and improved knowledge of the environments around the moons of interest is important for probing sub-surface oceans that may be habitable. Here we review the magnetosphere and plasma science that will be enabled by JUICE from arrival at Jupiter in July 2031. We focus on the specific topics where the mission will push forward the boundaries of our understanding through a combination of the spacecraft trajectory through the system and the measurements that will be made by its suite of scientific instruments. Advances during the initial orbits around Jupiter will include construction of a comprehensive picture of the poorly understood region of Jupiter{\textquoteright}s magnetosphere where rigid plasma rotation with the planet breaks down, and new perspectives on how Jupiter{\textquoteright}s magnetosphere interacts with both Europa and Callisto. The later orbits around Ganymede will dramatically improve knowledge of this moon{\textquoteright}s smaller magnetosphere embedded within the larger magnetosphere of Jupiter. We conclude by outlining the high-level operational strategy that will support this broad science return.",

keywords = "Callisto, Europa, Ganymede, Jupiter, Magnetospheres, Space plasmas",

author = "A. Masters and R. Modolo and E. Roussos and N. Krupp and O. Witasse and C. Vallat and B. Cecconi and Edberg, \{N. J.T.\} and Y. Futaana and M. Galand and D. Heyner and M. Holmberg and H. Huybrighs and X. Jia and K. Khurana and L. Lamy and L. Roth and A. Sulaiman and P. Tortora and S. Barabash and L. Bruzzone and Dougherty, \{M. K.\} and R. Gladstone and Gurvits, \{L. I.\} and P. Hartogh and H. Hussmann and L. Iess and F. Poulet and Wahlund, \{J. E.\} and Andrews, \{D. J.\} and Arridge, \{C. S.\} and F. Bagenal and C. Baskevitch and J. Bergman and Bocanegra, \{T. M.\} and P. Brandt and Bunce, \{E. J.\} and G. Clark and Coates, \{A. J.\} and E. Galanti and A. Galli and D. Grodent and G. Jones and Y. Kasaba and Y. Kaspi and Y. Katoh and N. Kaweeyanun and Y. Khotyaintsev and T. Kimura and P. Kollmann and D. Mitchell and A. Moirano and G. Molera Calv{\'e}s and M. Morooka and M{\"u}ller-Wodarg, \{I. C.F.\} and C. Mu{\~n}oz and A. Mura and M. P{\"a}tzold and M. Pinto and C. Plainaki and Retherford, \{K. D.\} and A. Retin{\`o} and H. Rothkaehl and O. Santol{\'i}k and J. Saur and G. Stenberg Wieser and F. Tsuchiya and M. Volwerk and A. Vorburger and P. Wurz and M. Zannoni",

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

year = "2025",

month = mar,

day = "1",

doi = "10.1007/s11214-025-01148-8",

language = "English",

volume = "221",

journal = "Space Science Reviews",

issn = "0038-6308",

number = "2",

}

Masters, A, Modolo, R, Roussos, E, Krupp, N, Witasse, O, Vallat, C, Cecconi, B, Edberg, NJT, Futaana, Y, Galand, M, Heyner, D, Holmberg, M, Huybrighs, H, Jia, X, Khurana, K, Lamy, L, Roth, L, Sulaiman, A, Tortora, P, Barabash, S, Bruzzone, L, Dougherty, MK, Gladstone, R, Gurvits, LI, Hartogh, P, Hussmann, H, Iess, L, Poulet, F, Wahlund, JE, Andrews, DJ, Arridge, CS, Bagenal, F, Baskevitch, C, Bergman, J, Bocanegra, TM, Brandt, P, Bunce, EJ, Clark, G, Coates, AJ, Galanti, E, Galli, A, Grodent, D, Jones, G, Kasaba, Y, Kaspi, Y, Katoh, Y, Kaweeyanun, N, Khotyaintsev, Y, Kimura, T, Kollmann, P, Mitchell, D, Moirano, A, Molera Calvés, G, Morooka, M, Müller-Wodarg, ICF, Muñoz, C, Mura, A, Pätzold, M, Pinto, M, Plainaki, C, Retherford, KD, Retinò, A, Rothkaehl, H, Santolík, O, Saur, J, Stenberg Wieser, G, Tsuchiya, F, Volwerk, M, Vorburger, A, Wurz, P & Zannoni, M 2025, 'Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer', Space Science Reviews, vol. 221, no. 2, 24. https://doi.org/10.1007/s11214-025-01148-8

TY - JOUR

T1 - Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer

AU - Masters, A.

AU - Modolo, R.

AU - Roussos, E.

AU - Krupp, N.

AU - Witasse, O.

AU - Vallat, C.

AU - Cecconi, B.

AU - Edberg, N. J.T.

AU - Futaana, Y.

AU - Galand, M.

AU - Heyner, D.

AU - Holmberg, M.

AU - Huybrighs, H.

AU - Jia, X.

AU - Khurana, K.

AU - Lamy, L.

AU - Roth, L.

AU - Sulaiman, A.

AU - Tortora, P.

AU - Barabash, S.

AU - Bruzzone, L.

AU - Dougherty, M. K.

AU - Gladstone, R.

AU - Gurvits, L. I.

AU - Hartogh, P.

AU - Hussmann, H.

AU - Iess, L.

AU - Poulet, F.

AU - Wahlund, J. E.

AU - Andrews, D. J.

AU - Arridge, C. S.

AU - Bagenal, F.

AU - Baskevitch, C.

AU - Bergman, J.

AU - Bocanegra, T. M.

AU - Brandt, P.

AU - Bunce, E. J.

AU - Clark, G.

AU - Coates, A. J.

AU - Galanti, E.

AU - Galli, A.

AU - Grodent, D.

AU - Jones, G.

AU - Kasaba, Y.

AU - Kaspi, Y.

AU - Katoh, Y.

AU - Kaweeyanun, N.

AU - Khotyaintsev, Y.

AU - Kimura, T.

AU - Kollmann, P.

AU - Mitchell, D.

AU - Moirano, A.

AU - Molera Calvés, G.

AU - Morooka, M.

AU - Müller-Wodarg, I. C.F.

AU - Muñoz, C.

AU - Mura, A.

AU - Pätzold, M.

AU - Pinto, M.

AU - Plainaki, C.

AU - Retherford, K. D.

AU - Retinò, A.

AU - Rothkaehl, H.

AU - Santolík, O.

AU - Saur, J.

AU - Stenberg Wieser, G.

AU - Tsuchiya, F.

AU - Volwerk, M.

AU - Vorburger, A.

AU - Wurz, P.

AU - Zannoni, M.

PY - 2025/3/1

Y1 - 2025/3/1

N2 - The Jupiter Icy Moons Explorer (JUICE) is a European Space Agency mission to explore Jupiter and its three icy Galilean moons: Europa, Ganymede, and Callisto. Numerous JUICE investigations concern the magnetised space environments containing low-density populations of charged particles that surround each of these bodies. In the case of both Jupiter and Ganymede, the magnetic field generated internally produces a surrounding volume of space known as a magnetosphere. All these regions are natural laboratories where we can test and further our understanding of how such systems work, and improved knowledge of the environments around the moons of interest is important for probing sub-surface oceans that may be habitable. Here we review the magnetosphere and plasma science that will be enabled by JUICE from arrival at Jupiter in July 2031. We focus on the specific topics where the mission will push forward the boundaries of our understanding through a combination of the spacecraft trajectory through the system and the measurements that will be made by its suite of scientific instruments. Advances during the initial orbits around Jupiter will include construction of a comprehensive picture of the poorly understood region of Jupiter’s magnetosphere where rigid plasma rotation with the planet breaks down, and new perspectives on how Jupiter’s magnetosphere interacts with both Europa and Callisto. The later orbits around Ganymede will dramatically improve knowledge of this moon’s smaller magnetosphere embedded within the larger magnetosphere of Jupiter. We conclude by outlining the high-level operational strategy that will support this broad science return.

AB - The Jupiter Icy Moons Explorer (JUICE) is a European Space Agency mission to explore Jupiter and its three icy Galilean moons: Europa, Ganymede, and Callisto. Numerous JUICE investigations concern the magnetised space environments containing low-density populations of charged particles that surround each of these bodies. In the case of both Jupiter and Ganymede, the magnetic field generated internally produces a surrounding volume of space known as a magnetosphere. All these regions are natural laboratories where we can test and further our understanding of how such systems work, and improved knowledge of the environments around the moons of interest is important for probing sub-surface oceans that may be habitable. Here we review the magnetosphere and plasma science that will be enabled by JUICE from arrival at Jupiter in July 2031. We focus on the specific topics where the mission will push forward the boundaries of our understanding through a combination of the spacecraft trajectory through the system and the measurements that will be made by its suite of scientific instruments. Advances during the initial orbits around Jupiter will include construction of a comprehensive picture of the poorly understood region of Jupiter’s magnetosphere where rigid plasma rotation with the planet breaks down, and new perspectives on how Jupiter’s magnetosphere interacts with both Europa and Callisto. The later orbits around Ganymede will dramatically improve knowledge of this moon’s smaller magnetosphere embedded within the larger magnetosphere of Jupiter. We conclude by outlining the high-level operational strategy that will support this broad science return.

KW - Callisto

KW - Europa

KW - Ganymede

KW - Jupiter

KW - Magnetospheres

KW - Space plasmas

UR - https://www.scopus.com/pages/publications/105012447612

U2 - 10.1007/s11214-025-01148-8

DO - 10.1007/s11214-025-01148-8

M3 - Article

AN - SCOPUS:105012447612

SN - 0038-6308

VL - 221

JO - Space Science Reviews

JF - Space Science Reviews

IS - 2

M1 - 24

ER -

Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer

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Keywords

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