Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L-Band Imager

Alessandro Moirano; Alessandro Mura; Alberto Adriani; Vincent Dols; Bertrand Bonfond; Jack H. Waite; Vincent Hue; Jamey R. Szalay; Ali H. Sulaiman; Bianca M. Dinelli; Federico Tosi; Francesca Altieri; Andrea Cicchetti; Gianrico Filacchione; Davide Grassi; Alessandra Migliorini; Maria L. Moriconi; Raffaella Noschese; Giuseppe Piccioni; Roberto Sordini; Diego Turrini; Christina Plainaki; Giuseppe Sindoni; Stefano Massetti; Robert L. Lysak; Stavro L. Ivanovski; Scott J. Bolton

doi:10.1029/2021JA029450

Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L-Band Imager

Alessandro Moirano, Alessandro Mura, Alberto Adriani, Vincent Dols, Bertrand Bonfond, Jack H. Waite, Vincent Hue, Jamey R. Szalay, Ali H. Sulaiman, Bianca M. Dinelli, Federico Tosi, Francesca Altieri, Andrea Cicchetti, Gianrico Filacchione, Davide Grassi, Alessandra Migliorini, Maria L. Moriconi, Raffaella Noschese, Giuseppe Piccioni, Roberto SordiniDiego Turrini, Christina Plainaki, Giuseppe Sindoni, Stefano Massetti, Robert L. Lysak, Stavro L. Ivanovski, Scott J. Bolton

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Abstract

Jupiter hosts intense auroral activity associated with charged particles precipitating into the planet's atmosphere. The Galilean moons orbiting within the magnetosphere are swept by the magnetic field: the resulting perturbation travels along field lines as Alfven waves, which are able to accelerate electrons toward the planet, producing satellite-induced auroral emissions. These emissions due to the moons, known as footprints, can be detected in various wavelengths (UV, visible, IR) outside the main auroral emission as multiple bright spots followed by footprint tails. Since 2016 the Juno spacecraft orbiting Jupiter has surveyed the polar regions more than 30 times at close distances. Onboard the spacecraft, the Jovian InfraRed Auroral Mapper (JIRAM) is an imager and spectrometer with an L-band imaging filter suited to observe auroral features at unprecedented spatial resolution. JIRAM revealed a rich substructure in the footprint tails of Io, Europa, and Ganymede, which appear as a trail of quasi-regularly spaced bright sub-dots whose intensity fades away along the emission trail as the spatial separation from the footprint increases. The fine structure of the Europa and Ganymede footprint tails is reported in this work for the first time. We will also show that the typical distance between subsequent sub-dots is the same for all three moons at JIRAM resolution in both hemispheres. In addition, the sub-dots observed by JIRAM are static in a frame corotating with Jupiter. A feedback mechanism between the ionosphere and the magnetosphere is suggested as a potential candidate to explain the morphology of the footprint tails.

Original language	English (US)
Article number	e2021JA029450
Journal	Journal of Geophysical Research: Space Physics
Volume	126
Issue number	9
DOIs	https://doi.org/10.1029/2021JA029450
State	Published - Sep 2021
Externally published	Yes

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Publisher Copyright:
© 2021. The Authors.

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Moirano, A., Mura, A., Adriani, A., Dols, V., Bonfond, B., Waite, J. H., Hue, V., Szalay, J. R., Sulaiman, A. H., Dinelli, B. M., Tosi, F., Altieri, F., Cicchetti, A., Filacchione, G., Grassi, D., Migliorini, A., Moriconi, M. L., Noschese, R., Piccioni, G., ... Bolton, S. J. (2021). Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L-Band Imager. Journal of Geophysical Research: Space Physics, 126(9), Article e2021JA029450. https://doi.org/10.1029/2021JA029450

Moirano, A, Mura, A, Adriani, A, Dols, V, Bonfond, B, Waite, JH, Hue, V, Szalay, JR, Sulaiman, AH, Dinelli, BM, Tosi, F, Altieri, F, Cicchetti, A, Filacchione, G, Grassi, D, Migliorini, A, Moriconi, ML, Noschese, R, Piccioni, G, Sordini, R, Turrini, D, Plainaki, C, Sindoni, G, Massetti, S, Lysak, RL, Ivanovski, SL & Bolton, SJ 2021, 'Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L-Band Imager', Journal of Geophysical Research: Space Physics, vol. 126, no. 9, e2021JA029450. https://doi.org/10.1029/2021JA029450

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title = "Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L-Band Imager",

abstract = "Jupiter hosts intense auroral activity associated with charged particles precipitating into the planet's atmosphere. The Galilean moons orbiting within the magnetosphere are swept by the magnetic field: the resulting perturbation travels along field lines as Alfven waves, which are able to accelerate electrons toward the planet, producing satellite-induced auroral emissions. These emissions due to the moons, known as footprints, can be detected in various wavelengths (UV, visible, IR) outside the main auroral emission as multiple bright spots followed by footprint tails. Since 2016 the Juno spacecraft orbiting Jupiter has surveyed the polar regions more than 30 times at close distances. Onboard the spacecraft, the Jovian InfraRed Auroral Mapper (JIRAM) is an imager and spectrometer with an L-band imaging filter suited to observe auroral features at unprecedented spatial resolution. JIRAM revealed a rich substructure in the footprint tails of Io, Europa, and Ganymede, which appear as a trail of quasi-regularly spaced bright sub-dots whose intensity fades away along the emission trail as the spatial separation from the footprint increases. The fine structure of the Europa and Ganymede footprint tails is reported in this work for the first time. We will also show that the typical distance between subsequent sub-dots is the same for all three moons at JIRAM resolution in both hemispheres. In addition, the sub-dots observed by JIRAM are static in a frame corotating with Jupiter. A feedback mechanism between the ionosphere and the magnetosphere is suggested as a potential candidate to explain the morphology of the footprint tails.",

author = "Alessandro Moirano and Alessandro Mura and Alberto Adriani and Vincent Dols and Bertrand Bonfond and Waite, {Jack H.} and Vincent Hue and Szalay, {Jamey R.} and Sulaiman, {Ali H.} and Dinelli, {Bianca M.} and Federico Tosi and Francesca Altieri and Andrea Cicchetti and Gianrico Filacchione and Davide Grassi and Alessandra Migliorini and Moriconi, {Maria L.} and Raffaella Noschese and Giuseppe Piccioni and Roberto Sordini and Diego Turrini and Christina Plainaki and Giuseppe Sindoni and Stefano Massetti and Lysak, {Robert L.} and Ivanovski, {Stavro L.} and Bolton, {Scott J.}",

note = "Publisher Copyright: {\textcopyright} 2021. The Authors.",

year = "2021",

month = sep,

doi = "10.1029/2021JA029450",

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volume = "126",

journal = "Journal of Geophysical Research: Space Physics",

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T1 - Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L-Band Imager

AU - Moirano, Alessandro

AU - Mura, Alessandro

AU - Adriani, Alberto

AU - Dols, Vincent

AU - Bonfond, Bertrand

AU - Waite, Jack H.

AU - Hue, Vincent

AU - Szalay, Jamey R.

AU - Sulaiman, Ali H.

AU - Dinelli, Bianca M.

AU - Tosi, Federico

AU - Altieri, Francesca

AU - Cicchetti, Andrea

AU - Filacchione, Gianrico

AU - Grassi, Davide

AU - Migliorini, Alessandra

AU - Moriconi, Maria L.

AU - Noschese, Raffaella

AU - Piccioni, Giuseppe

AU - Sordini, Roberto

AU - Turrini, Diego

AU - Plainaki, Christina

AU - Sindoni, Giuseppe

AU - Massetti, Stefano

AU - Lysak, Robert L.

AU - Ivanovski, Stavro L.

AU - Bolton, Scott J.

PY - 2021/9

Y1 - 2021/9

N2 - Jupiter hosts intense auroral activity associated with charged particles precipitating into the planet's atmosphere. The Galilean moons orbiting within the magnetosphere are swept by the magnetic field: the resulting perturbation travels along field lines as Alfven waves, which are able to accelerate electrons toward the planet, producing satellite-induced auroral emissions. These emissions due to the moons, known as footprints, can be detected in various wavelengths (UV, visible, IR) outside the main auroral emission as multiple bright spots followed by footprint tails. Since 2016 the Juno spacecraft orbiting Jupiter has surveyed the polar regions more than 30 times at close distances. Onboard the spacecraft, the Jovian InfraRed Auroral Mapper (JIRAM) is an imager and spectrometer with an L-band imaging filter suited to observe auroral features at unprecedented spatial resolution. JIRAM revealed a rich substructure in the footprint tails of Io, Europa, and Ganymede, which appear as a trail of quasi-regularly spaced bright sub-dots whose intensity fades away along the emission trail as the spatial separation from the footprint increases. The fine structure of the Europa and Ganymede footprint tails is reported in this work for the first time. We will also show that the typical distance between subsequent sub-dots is the same for all three moons at JIRAM resolution in both hemispheres. In addition, the sub-dots observed by JIRAM are static in a frame corotating with Jupiter. A feedback mechanism between the ionosphere and the magnetosphere is suggested as a potential candidate to explain the morphology of the footprint tails.

AB - Jupiter hosts intense auroral activity associated with charged particles precipitating into the planet's atmosphere. The Galilean moons orbiting within the magnetosphere are swept by the magnetic field: the resulting perturbation travels along field lines as Alfven waves, which are able to accelerate electrons toward the planet, producing satellite-induced auroral emissions. These emissions due to the moons, known as footprints, can be detected in various wavelengths (UV, visible, IR) outside the main auroral emission as multiple bright spots followed by footprint tails. Since 2016 the Juno spacecraft orbiting Jupiter has surveyed the polar regions more than 30 times at close distances. Onboard the spacecraft, the Jovian InfraRed Auroral Mapper (JIRAM) is an imager and spectrometer with an L-band imaging filter suited to observe auroral features at unprecedented spatial resolution. JIRAM revealed a rich substructure in the footprint tails of Io, Europa, and Ganymede, which appear as a trail of quasi-regularly spaced bright sub-dots whose intensity fades away along the emission trail as the spatial separation from the footprint increases. The fine structure of the Europa and Ganymede footprint tails is reported in this work for the first time. We will also show that the typical distance between subsequent sub-dots is the same for all three moons at JIRAM resolution in both hemispheres. In addition, the sub-dots observed by JIRAM are static in a frame corotating with Jupiter. A feedback mechanism between the ionosphere and the magnetosphere is suggested as a potential candidate to explain the morphology of the footprint tails.

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M1 - e2021JA029450

ER -

Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L-Band Imager

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