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Observation and origin of non-thermal hard X-rays from Jupiter

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Observation and origin of non-thermal hard X-rays from Jupiter. / Mori, Kaya; Hailey, Charles; Bridges, Gabriel et al.
In: Nature Astronomy, Vol. 6, No. 4, 30.04.2022, p. 442-448.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Mori, K, Hailey, C, Bridges, G, Mandel, S, Garvin, A, Grefenstette, B, Dunn, WR, Hord, B, Branduardi-Raymont, G, Clarke, J, Jackman, CM, Nynka, M & Ray, LC 2022, 'Observation and origin of non-thermal hard X-rays from Jupiter', Nature Astronomy, vol. 6, no. 4, pp. 442-448. https://doi.org/10.1038/s41550-021-01594-8

APA

Mori, K., Hailey, C., Bridges, G., Mandel, S., Garvin, A., Grefenstette, B., Dunn, W. R., Hord, B., Branduardi-Raymont, G., Clarke, J., Jackman, C. M., Nynka, M., & Ray, L. C. (2022). Observation and origin of non-thermal hard X-rays from Jupiter. Nature Astronomy, 6(4), 442-448. https://doi.org/10.1038/s41550-021-01594-8

Vancouver

Mori K, Hailey C, Bridges G, Mandel S, Garvin A, Grefenstette B et al. Observation and origin of non-thermal hard X-rays from Jupiter. Nature Astronomy. 2022 Apr 30;6(4):442-448. Epub 2022 Feb 10. doi: 10.1038/s41550-021-01594-8

Author

Mori, Kaya ; Hailey, Charles ; Bridges, Gabriel et al. / Observation and origin of non-thermal hard X-rays from Jupiter. In: Nature Astronomy. 2022 ; Vol. 6, No. 4. pp. 442-448.

Bibtex

@article{1892e52c4cfe4504bb66113773dab7bc,
title = "Observation and origin of non-thermal hard X-rays from Jupiter",
abstract = "Electrons accelerated on Earth by a rich variety of wave-scattering or stochastic processes generate hard, non-thermal X-ray bremsstrahlung up to ~1 MeV and power Earth{\textquoteright}s various types of aurorae. Although Jupiter{\textquoteright}s magnetic field is an order of magnitude larger than Earth{\textquoteright}s, space-based telescopes have previously detected X-rays only up to ~7 keV. On the basis of theoretical models of the Jovian auroral X-ray production, X-ray emission in the ~2–7 keV band has been interpreted as thermal (arising from electrons characterized by a Maxwell–Boltzmann distribution) bremsstrahlung. Here we report the observation of hard X-rays in the 8–20 keV band from the Jovian aurorae, obtained with the NuSTAR X-ray observatory. The X-rays fit to a flat power-law model with slope of 0.60 ± 0.22—a spectral signature of non-thermal, hard X-ray bremsstrahlung. We determine the electron flux and spectral shape in the kiloelectronvolt to megaelectronvolt energy range using coeval in situ measurements taken by the Juno spacecraft{\textquoteright}s JADE and JEDI instruments. Jovian electron spectra of the form we observe have previously been interpreted as arising in stochastic acceleration, rather than coherent acceleration by electric fields. We reproduce the X-ray spectral shape and approximate flux observed by NuSTAR, and explain the non-detection of hard X-rays by Ulysses, by simulating the non-thermal population of electrons undergoing precipitating electron energy loss, secondary electron generation and bremsstrahlung emission in a model Jovian atmosphere. The results highlight the similarities between the processes generating hard X-ray aurorae on Earth and Jupiter, which may be occurring on Saturn, too.",
author = "Kaya Mori and Charles Hailey and Gabriel Bridges and Shifra Mandel and Amani Garvin and Brian Grefenstette and W.R. Dunn and Benjamin Hord and Graziella Branduardi-Raymont and John Clarke and Jackman, {Caitriona M.} and Melania Nynka and Ray, {Licia C}",
year = "2022",
month = apr,
day = "30",
doi = "10.1038/s41550-021-01594-8",
language = "English",
volume = "6",
pages = "442--448",
journal = "Nature Astronomy",
issn = "2397-3366",
publisher = "Nature Publishing Group",
number = "4",

}

RIS

TY - JOUR

T1 - Observation and origin of non-thermal hard X-rays from Jupiter

AU - Mori, Kaya

AU - Hailey, Charles

AU - Bridges, Gabriel

AU - Mandel, Shifra

AU - Garvin, Amani

AU - Grefenstette, Brian

AU - Dunn, W.R.

AU - Hord, Benjamin

AU - Branduardi-Raymont, Graziella

AU - Clarke, John

AU - Jackman, Caitriona M.

AU - Nynka, Melania

AU - Ray, Licia C

PY - 2022/4/30

Y1 - 2022/4/30

N2 - Electrons accelerated on Earth by a rich variety of wave-scattering or stochastic processes generate hard, non-thermal X-ray bremsstrahlung up to ~1 MeV and power Earth’s various types of aurorae. Although Jupiter’s magnetic field is an order of magnitude larger than Earth’s, space-based telescopes have previously detected X-rays only up to ~7 keV. On the basis of theoretical models of the Jovian auroral X-ray production, X-ray emission in the ~2–7 keV band has been interpreted as thermal (arising from electrons characterized by a Maxwell–Boltzmann distribution) bremsstrahlung. Here we report the observation of hard X-rays in the 8–20 keV band from the Jovian aurorae, obtained with the NuSTAR X-ray observatory. The X-rays fit to a flat power-law model with slope of 0.60 ± 0.22—a spectral signature of non-thermal, hard X-ray bremsstrahlung. We determine the electron flux and spectral shape in the kiloelectronvolt to megaelectronvolt energy range using coeval in situ measurements taken by the Juno spacecraft’s JADE and JEDI instruments. Jovian electron spectra of the form we observe have previously been interpreted as arising in stochastic acceleration, rather than coherent acceleration by electric fields. We reproduce the X-ray spectral shape and approximate flux observed by NuSTAR, and explain the non-detection of hard X-rays by Ulysses, by simulating the non-thermal population of electrons undergoing precipitating electron energy loss, secondary electron generation and bremsstrahlung emission in a model Jovian atmosphere. The results highlight the similarities between the processes generating hard X-ray aurorae on Earth and Jupiter, which may be occurring on Saturn, too.

AB - Electrons accelerated on Earth by a rich variety of wave-scattering or stochastic processes generate hard, non-thermal X-ray bremsstrahlung up to ~1 MeV and power Earth’s various types of aurorae. Although Jupiter’s magnetic field is an order of magnitude larger than Earth’s, space-based telescopes have previously detected X-rays only up to ~7 keV. On the basis of theoretical models of the Jovian auroral X-ray production, X-ray emission in the ~2–7 keV band has been interpreted as thermal (arising from electrons characterized by a Maxwell–Boltzmann distribution) bremsstrahlung. Here we report the observation of hard X-rays in the 8–20 keV band from the Jovian aurorae, obtained with the NuSTAR X-ray observatory. The X-rays fit to a flat power-law model with slope of 0.60 ± 0.22—a spectral signature of non-thermal, hard X-ray bremsstrahlung. We determine the electron flux and spectral shape in the kiloelectronvolt to megaelectronvolt energy range using coeval in situ measurements taken by the Juno spacecraft’s JADE and JEDI instruments. Jovian electron spectra of the form we observe have previously been interpreted as arising in stochastic acceleration, rather than coherent acceleration by electric fields. We reproduce the X-ray spectral shape and approximate flux observed by NuSTAR, and explain the non-detection of hard X-rays by Ulysses, by simulating the non-thermal population of electrons undergoing precipitating electron energy loss, secondary electron generation and bremsstrahlung emission in a model Jovian atmosphere. The results highlight the similarities between the processes generating hard X-ray aurorae on Earth and Jupiter, which may be occurring on Saturn, too.

U2 - 10.1038/s41550-021-01594-8

DO - 10.1038/s41550-021-01594-8

M3 - Journal article

VL - 6

SP - 442

EP - 448

JO - Nature Astronomy

JF - Nature Astronomy

SN - 2397-3366

IS - 4

ER -