Jupiter’s magnetosphere and aurorae observed by the Juno spacecraft during its first polar orbits

Connerney, J. E. P.; Adriani, A.; Allegrini, F.; Bagenal, F.; Bolton, S. J.; Bonfond, Bertrand; Cowley, S. W. H.; Gérard, Jean‐Claude; Gladstone, G. R.; Grodent, Denis; Hospodarsky, G. B.; Jørgensen, John Leif; Kurth, W. S.; Levin, S. M.; Mauk, B. H.; McComas, D. J.; Mura, A.; Paranicas, C.; Smith, E. J.; Thorne, R. M.; Valek, P. W.; Waite, J. H.

doi:10.1126/science.aam5928

Cited by 124 publications

(163 citation statements)

References 38 publications

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“…The previous work discussed earlier focused on ions with incident energies between 1 and 2 MeV/u, as these high ion energies are responsible for X‐ray emissions. However, we now know that ions with a wide range of energies precipitate into the polar cap, as confirmed by National Aeronautics and Space Administration (NASA)'s Juno spacecraft (Clark, Mauk, Haggerty, et al, ; Clark, Mauk, Paranicas, et al, ; Connerney et al, ; Haggerty et al, ; Szalay et al, ). Hence, we now model a much broader range of incident ion energies than previously considered (i.e., from 10 keV/u to 5 MeV/u).…”

Section: Physical Processes and Model Descriptionmentioning

confidence: 95%

Jovian Auroral Ion Precipitation: Field‐Aligned Currents and Ultraviolet Emissions

et al. 2018

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A model is described for the transport of magnetospheric oxygen ions with low charge state and energies up to several MeV/nucleon (MeV/u) as they precipitate into Jupiter's polar atmosphere. A revised and updated hybrid Monte Carlo model originally developed by Ozak et al. (2010, https://doi.org/10.1029/2010JA015635) is used to model the Jovian X‐ray aurora. The current model uses a wide range of incident oxygen ion energies (10 keV/u to 5 MeV/u) and the most up‐to‐date collision cross sections. In addition, the effects of the secondary electrons generated from the heavy ion precipitation are included using a two‐stream transport model that computes the secondary electron fluxes and their escape from the atmosphere. The model also determines H2 Lyman‐Werner band emission intensities, including a predicted spectrum and the associated color ratio. Implications of the new model results for interpretation of data from National Aeronautics and Space Administration's Juno mission are discussed. In particular, the model predicts that for a 2 MeV/u oxygen ion energy input of 10 mW/m2: (1) escaping electrons are produced with an energy range from 1 eV to 4 keV, which is a smaller range than previous models by Ozak et al. (2013, https://doi.org/10.1002/2013GL50812) predicted, (2) H2 band emission rates of 75 kR are generated, similar to previous estimates, and (3) a newly calculated Lyman and Werner band color ratio of 10 is expected. The color ratios are put into a context of various methane number density distributions.

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Section: Physical Processes and Model Descriptionmentioning

confidence: 95%

Jovian Auroral Ion Precipitation: Field‐Aligned Currents and Ultraviolet Emissions

et al. 2018

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“…As it cruised through the large-scale magnetopause boundary layer, its instruments measured intense bursts of radio emissions and energetic particles (both electrons and protons), with timescales ranging from 2 to 80 min (Karanikola et al, 2004;MacDowall et al, 1993;McKibben et al, 1993;Zhang et al, 1995). The instrument suite and the polar orbit of the Juno spacecraft are well suited to perform this investigation Bolton et al, 2017;Connerney et al, 2017). At the onset of the electron and proton bursts, the pitch angle distributions were field aligned and monodirectional, with the particles originating from Jupiter's aurora.…”

Section: Introductionmentioning

confidence: 99%

Bar Code Events in the Juno‐UVS Data: Signature ∼10 MeV Electron Microbursts at Jupiter

Bonfond

Gladstone

Grodent

et al. 2018

Geophysical Research Letters

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One of the most intriguing discoveries of Juno is the quasi‐systematic detection of upgoing electrons above the auroral regions. Here we discuss a by‐product of the most energetic component of this population: a contamination resembling bar codes in the Juno‐UVS images. This pattern is likely caused by bursts of ∼10 MeV electrons penetrating the instrument. These events are mostly detected when Juno's magnetic footprint is located poleward of the main emission relative to the magnetic pole. The signal is not periodic, but the bursts are typically 0.1–1 s apart. They are essentially detected when Juno‐UVS is oriented toward Jupiter, indicating that the signal is due to upgoing electrons. The event detections occur between 1 and 7 Jovian radii above the 1‐bar level, suggesting that the electron acceleration takes place close to Jupiter and is thus both strong and brief.

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“…The strong magnetic field of Jupiter (around 6 Gauss at the surface) could affect the flow field at depth with modestly high electrical conductivity [Liu et al, 2008;Heimpel and Gómez Pérez, 2011;Gastine et al, 2014;Jones, 2014;Connerney et al, 2017]. The strong magnetic field of Jupiter (around 6 Gauss at the surface) could affect the flow field at depth with modestly high electrical conductivity [Liu et al, 2008;Heimpel and Gómez Pérez, 2011;Gastine et al, 2014;Jones, 2014;Connerney et al, 2017].…”

Section: Introductionmentioning

confidence: 99%

Constraining Jupiter's internal flows using Juno magnetic and gravity measurements

Galanti

Cao

Kaspi

2017

Geophysical Research Letters

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Deciphering the flow below the cloud‐level of Jupiter remains a critical milestone in understanding Jupiter's internal structure and dynamics. The expected high‐precision Juno measurements of both the gravity field and the magnetic field might help to reach this goal. Here we propose a method that combines both fields to constrain the depth‐dependent flow field inside Jupiter. This method is based on a mean‐field electrodynamic balance that relates the flow field to the anomalous magnetic field, and geostrophic balance that relates the flow field to the anomalous gravity field. We find that the flow field has two distinct regions of influence: an upper region in which the flow affects mostly the gravity field and a lower region in which the flow affects mostly the magnetic field. An optimization procedure allows to reach a unified flow structure that is consistent with both the gravity and the magnetic fields.

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Jupiter’s magnetosphere and aurorae observed by the Juno spacecraft during its first polar orbits

Cited by 124 publications

References 38 publications

Jovian Auroral Ion Precipitation: Field‐Aligned Currents and Ultraviolet Emissions

Jovian Auroral Ion Precipitation: Field‐Aligned Currents and Ultraviolet Emissions

Bar Code Events in the Juno‐UVS Data: Signature ∼10 MeV Electron Microbursts at Jupiter

Constraining Jupiter's internal flows using Juno magnetic and gravity measurements

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