Maximum Energies of Trapped Particles Around Magnetized Planets and Small Bodies

Rona Oran; Benjamin P. Weiss; Maria De Soria Santacruz-Pich; Insoo Jun; David J. Lawrence; Carol A. Polanskey; J. Martin Ratliff; Carol A. Raymond; Jodie B. Ream; Christopher T. Russell; Yuri Y. Shprits; Maria T. Zuber; Linda T. Elkins-Tanton

doi:10.1029/2021GL097014

Maximum Energies of Trapped Particles Around Magnetized Planets and Small Bodies

Rona Oran, Benjamin P. Weiss, Maria De Soria Santacruz-Pich, Insoo Jun, David J. Lawrence, Carol A. Polanskey, J. Martin Ratliff, Carol A. Raymond, Jodie B. Ream, Christopher T. Russell, Yuri Y. Shprits, Maria T. Zuber, Linda T. Elkins-Tanton

Earth and Space Exploration, School of (SESE)

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

3 Scopus citations

Abstract

Energetic charged particles trapped in planetary radiation belts are hazardous to spacecraft. Planned missions to iron-rich asteroids with possible strong remanent magnetic fields require an assessment of trapped particles energies. Using laboratory measurements of iron meteorites, we estimate the largest possible asteroid magnetic moment. Although weak compared to moments of planetary dynamos, the small body size may yield strong surface fields. We use hybrid simulations to confirm the formation of a magnetosphere with an extended quasi-dipolar region. However, the short length scale of the field implies that energetic particle motion would be nonadiabatic, making existing radiation belt theories not applicable. Our idealized particle simulations demonstrate that chaotic motions lead to particle loss at lower energies than those predicted by adiabatic theory, which may explain the energies of transiently trapped particles observed at Mercury, Ganymede, and Earth. However, even the most magnetized asteroids are unlikely to stably trap hazardous particles.

Original language	English (US)
Article number	e2021GL097014
Journal	Geophysical Research Letters
Volume	49
Issue number	13
DOIs	https://doi.org/10.1029/2021GL097014
State	Published - Jul 16 2022

Keywords

(16) Psyche
Psyche mission
asteroid magnetospheres
chaotic motion
energetic particles
hybrid simulations

ASJC Scopus subject areas

Geophysics
General Earth and Planetary Sciences

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10.1029/2021GL097014

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Oran, R., Weiss, B. P., De Soria Santacruz-Pich, M., Jun, I., Lawrence, D. J., Polanskey, C. A., Ratliff, J. M., Raymond, C. A., Ream, J. B., Russell, C. T., Shprits, Y. Y., Zuber, M. T., & Elkins-Tanton, L. T. (2022). Maximum Energies of Trapped Particles Around Magnetized Planets and Small Bodies. Geophysical Research Letters, 49(13), Article e2021GL097014. https://doi.org/10.1029/2021GL097014

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abstract = "Energetic charged particles trapped in planetary radiation belts are hazardous to spacecraft. Planned missions to iron-rich asteroids with possible strong remanent magnetic fields require an assessment of trapped particles energies. Using laboratory measurements of iron meteorites, we estimate the largest possible asteroid magnetic moment. Although weak compared to moments of planetary dynamos, the small body size may yield strong surface fields. We use hybrid simulations to confirm the formation of a magnetosphere with an extended quasi-dipolar region. However, the short length scale of the field implies that energetic particle motion would be nonadiabatic, making existing radiation belt theories not applicable. Our idealized particle simulations demonstrate that chaotic motions lead to particle loss at lower energies than those predicted by adiabatic theory, which may explain the energies of transiently trapped particles observed at Mercury, Ganymede, and Earth. However, even the most magnetized asteroids are unlikely to stably trap hazardous particles.",

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author = "Rona Oran and Weiss, {Benjamin P.} and {De Soria Santacruz-Pich}, Maria and Insoo Jun and Lawrence, {David J.} and Polanskey, {Carol A.} and Ratliff, {J. Martin} and Raymond, {Carol A.} and Ream, {Jodie B.} and Russell, {Christopher T.} and Shprits, {Yuri Y.} and Zuber, {Maria T.} and Elkins-Tanton, {Linda T.}",

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doi = "10.1029/2021GL097014",

language = "English (US)",

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AU - Lawrence, David J.

AU - Polanskey, Carol A.

AU - Ratliff, J. Martin

AU - Raymond, Carol A.

AU - Ream, Jodie B.

AU - Russell, Christopher T.

AU - Shprits, Yuri Y.

AU - Zuber, Maria T.

AU - Elkins-Tanton, Linda T.

PY - 2022/7/16

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N2 - Energetic charged particles trapped in planetary radiation belts are hazardous to spacecraft. Planned missions to iron-rich asteroids with possible strong remanent magnetic fields require an assessment of trapped particles energies. Using laboratory measurements of iron meteorites, we estimate the largest possible asteroid magnetic moment. Although weak compared to moments of planetary dynamos, the small body size may yield strong surface fields. We use hybrid simulations to confirm the formation of a magnetosphere with an extended quasi-dipolar region. However, the short length scale of the field implies that energetic particle motion would be nonadiabatic, making existing radiation belt theories not applicable. Our idealized particle simulations demonstrate that chaotic motions lead to particle loss at lower energies than those predicted by adiabatic theory, which may explain the energies of transiently trapped particles observed at Mercury, Ganymede, and Earth. However, even the most magnetized asteroids are unlikely to stably trap hazardous particles.

AB - Energetic charged particles trapped in planetary radiation belts are hazardous to spacecraft. Planned missions to iron-rich asteroids with possible strong remanent magnetic fields require an assessment of trapped particles energies. Using laboratory measurements of iron meteorites, we estimate the largest possible asteroid magnetic moment. Although weak compared to moments of planetary dynamos, the small body size may yield strong surface fields. We use hybrid simulations to confirm the formation of a magnetosphere with an extended quasi-dipolar region. However, the short length scale of the field implies that energetic particle motion would be nonadiabatic, making existing radiation belt theories not applicable. Our idealized particle simulations demonstrate that chaotic motions lead to particle loss at lower energies than those predicted by adiabatic theory, which may explain the energies of transiently trapped particles observed at Mercury, Ganymede, and Earth. However, even the most magnetized asteroids are unlikely to stably trap hazardous particles.

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Maximum Energies of Trapped Particles Around Magnetized Planets and Small Bodies

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