Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation

Physics

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https://doi.org/10.1002/jgra.50404
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Keywords

Saturn, aurora, magnetosphere, radio emissions

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Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation. / Lamy, L.; Prangé, R.; Pryor, W. et al.
In: Journal of Geophysical Research, Vol. 118, No. 8, 08.2013, p. 4817-4843.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Lamy, L, Prangé, R, Pryor, W, Gustin, J, Badman, SV, Melin, H, Stallard, T, Mitchell, DG & Brandt, PC 2013, 'Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation', Journal of Geophysical Research, vol. 118, no. 8, pp. 4817-4843. https://doi.org/10.1002/jgra.50404

APA

Lamy, L., Prangé, R., Pryor, W., Gustin, J., Badman, S. V., Melin, H., Stallard, T., Mitchell, D. G., & Brandt, P. C. (2013). Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation. Journal of Geophysical Research, 118(8), 4817-4843. https://doi.org/10.1002/jgra.50404

Vancouver

Lamy L, Prangé R, Pryor W, Gustin J, Badman SV, Melin H et al. Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation. Journal of Geophysical Research. 2013 Aug;118(8):4817-4843. doi: 10.1002/jgra.50404

Author

Lamy, L. ; Prangé, R. ; Pryor, W. et al. / Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation. In: Journal of Geophysical Research. 2013 ; Vol. 118, No. 8. pp. 4817-4843.

Bibtex

@article{9f95ee83b1ec4ed0a7d9c64fd1cd70ff,

title = "Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation",

abstract = "From 27 to 28 January 2009, the Cassini spacecraft remotely acquired combined observations of Saturn's southern aurorae at radio, ultraviolet, and infrared wavelengths, while monitoring ion injections in the middle magnetosphere from energetic neutral atoms. Simultaneous measurements included the sampling of a full planetary rotation, a relevant timescale to investigate auroral emissions driven by processes internal to the magnetosphere. In addition, this interval coincidentally matched a powerful substorm-like event in the magnetotail, which induced an overall dawnside intensification of the magnetospheric and auroral activity. We comparatively analyze this unique set of measurements to reach a comprehensive view of kronian auroral processes over the investigated timescale. We identify three source regions for the atmospheric aurorae, including a main oval associated with the bulk of Saturn Kilometric Radiation (SKR), together with polar and equatorward emissions. These observations reveal the coexistence of corotational and subcorototational dynamics of emissions associated with the main auroral oval. Precisely, we show that the atmospheric main oval hosts short-lived subcorotating isolated features together with a bright, longitudinally extended, corotating region locked at the southern SKR phase. We assign the substorm-like event to a regular, internally driven, nightside ion injection possibly triggered by a plasmoid ejection. We also investigate the total auroral energy budget, from the power input to the atmosphere, characterized by precipitating electrons up to 20 keV, to its dissipation through the various radiating processes. Finally, through simulations, we confirm the search-light nature of the SKR rotational modulation and we show that SKR arcs relate to isolated auroral spots. We characterize which radio sources are visible from the spacecraft and we estimate the fraction of visible southern power to a few percent. The resulting findings are discussed in the frame of pending questions as the persistence of a corotating field-aligned current system within a subcorotating magnetospheric cold plasma, the occurrence of plasmoid activity, and the comparison of auroral fluxes radiated at different wavelengths.",

keywords = "Saturn, aurora, magnetosphere, radio emissions",

author = "L. Lamy and R. Prang{\'e} and W. Pryor and J. Gustin and Badman, {S. V.} and H. Melin and T. Stallard and D. G. Mitchell and Brandt, {P. C.}",

note = "{\textcopyright}2013. American Geophysical Union",

year = "2013",

month = aug,

doi = "10.1002/jgra.50404",

language = "English",

volume = "118",

pages = "4817--4843",

journal = "Journal of Geophysical Research",

issn = "0148-0227",

publisher = "American Geophysical Union",

number = "8",

}

RIS

TY - JOUR

T1 - Multispectral simultaneous diagnosis of Saturn's aurorae throughout a planetary rotation

AU - Lamy, L.

AU - Prangé, R.

AU - Pryor, W.

AU - Gustin, J.

AU - Badman, S. V.

AU - Melin, H.

AU - Stallard, T.

AU - Mitchell, D. G.

AU - Brandt, P. C.

PY - 2013/8

Y1 - 2013/8

N2 - From 27 to 28 January 2009, the Cassini spacecraft remotely acquired combined observations of Saturn's southern aurorae at radio, ultraviolet, and infrared wavelengths, while monitoring ion injections in the middle magnetosphere from energetic neutral atoms. Simultaneous measurements included the sampling of a full planetary rotation, a relevant timescale to investigate auroral emissions driven by processes internal to the magnetosphere. In addition, this interval coincidentally matched a powerful substorm-like event in the magnetotail, which induced an overall dawnside intensification of the magnetospheric and auroral activity. We comparatively analyze this unique set of measurements to reach a comprehensive view of kronian auroral processes over the investigated timescale. We identify three source regions for the atmospheric aurorae, including a main oval associated with the bulk of Saturn Kilometric Radiation (SKR), together with polar and equatorward emissions. These observations reveal the coexistence of corotational and subcorototational dynamics of emissions associated with the main auroral oval. Precisely, we show that the atmospheric main oval hosts short-lived subcorotating isolated features together with a bright, longitudinally extended, corotating region locked at the southern SKR phase. We assign the substorm-like event to a regular, internally driven, nightside ion injection possibly triggered by a plasmoid ejection. We also investigate the total auroral energy budget, from the power input to the atmosphere, characterized by precipitating electrons up to 20 keV, to its dissipation through the various radiating processes. Finally, through simulations, we confirm the search-light nature of the SKR rotational modulation and we show that SKR arcs relate to isolated auroral spots. We characterize which radio sources are visible from the spacecraft and we estimate the fraction of visible southern power to a few percent. The resulting findings are discussed in the frame of pending questions as the persistence of a corotating field-aligned current system within a subcorotating magnetospheric cold plasma, the occurrence of plasmoid activity, and the comparison of auroral fluxes radiated at different wavelengths.

AB - From 27 to 28 January 2009, the Cassini spacecraft remotely acquired combined observations of Saturn's southern aurorae at radio, ultraviolet, and infrared wavelengths, while monitoring ion injections in the middle magnetosphere from energetic neutral atoms. Simultaneous measurements included the sampling of a full planetary rotation, a relevant timescale to investigate auroral emissions driven by processes internal to the magnetosphere. In addition, this interval coincidentally matched a powerful substorm-like event in the magnetotail, which induced an overall dawnside intensification of the magnetospheric and auroral activity. We comparatively analyze this unique set of measurements to reach a comprehensive view of kronian auroral processes over the investigated timescale. We identify three source regions for the atmospheric aurorae, including a main oval associated with the bulk of Saturn Kilometric Radiation (SKR), together with polar and equatorward emissions. These observations reveal the coexistence of corotational and subcorototational dynamics of emissions associated with the main auroral oval. Precisely, we show that the atmospheric main oval hosts short-lived subcorotating isolated features together with a bright, longitudinally extended, corotating region locked at the southern SKR phase. We assign the substorm-like event to a regular, internally driven, nightside ion injection possibly triggered by a plasmoid ejection. We also investigate the total auroral energy budget, from the power input to the atmosphere, characterized by precipitating electrons up to 20 keV, to its dissipation through the various radiating processes. Finally, through simulations, we confirm the search-light nature of the SKR rotational modulation and we show that SKR arcs relate to isolated auroral spots. We characterize which radio sources are visible from the spacecraft and we estimate the fraction of visible southern power to a few percent. The resulting findings are discussed in the frame of pending questions as the persistence of a corotating field-aligned current system within a subcorotating magnetospheric cold plasma, the occurrence of plasmoid activity, and the comparison of auroral fluxes radiated at different wavelengths.

KW - Saturn

KW - aurora

KW - magnetosphere

KW - radio emissions

U2 - 10.1002/jgra.50404

DO - 10.1002/jgra.50404

M3 - Journal article

VL - 118

SP - 4817

EP - 4843

JO - Journal of Geophysical Research

JF - Journal of Geophysical Research

SN - 0148-0227

IS - 8

ER -

Research

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