Proton Outflow Associated With Jupiter's Auroral Processes

Szalay, J. R.; Allegrini, F.; Bagenal, F.; Bolton, S. J.; Clark, G.; Connerney, J. E. P.; Ebert, R. W.; Ergun, R. E.; Mauk, B. H.; McComas, D. J.; Valek, P. W.; Wilson, R.

doi:10.1029/2020gl091627

Cited by 14 publications

(20 citation statements)

References 48 publications

(75 reference statements)

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“…Parallel electric fields that cause upward‐directed ion beams and conics in Earth's auroral cavity region have been found to be correlated with density depletions and are associated with auroral acceleration processes (Persoon et al., 1988). In fact, upward proton beams and ionospheric outflow associated with Jupiter's auroral emissions have been observed by Juno (Szalay et al., 2021).…”

Section: Resultsmentioning

confidence: 99%

The High‐Latitude Extension of Jupiter's Io Torus: Electron Densities Measured by Juno Waves

et al. 2021

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We present Jovian electron densities measured by the Juno Waves instrument at high‐latitudes (with magnetic latitudes of 50°−80°) on magnetic field lines threading the Io torus and plasma sheet (with M‐shells of 5.5−19) using the first 29 orbits of the Juno mission. We infer electron densities from characteristic frequency cutoffs and resonances in plasma wave spectra. Often more than one of the characteristic frequencies of the plasma can be identified, whose consistency provides credibility to the plasma density estimates. The majority of density measurements are on magnetic field lines threading the Io torus and intersecting Jupiter's ionosphere between Io's M‐shell and the auroral main oval, but there is evidence of density dropouts near and poleward of the auroral oval, which may be important in auroral particle acceleration. Sharp density gradients are found near field lines mapping to the inner edge of the Io torus M‐shells. These observations demonstrate the extension of elevated Io torus densities along field lines to higher latitudes.

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Section: Resultsmentioning

confidence: 99%

The High‐Latitude Extension of Jupiter's Io Torus: Electron Densities Measured by Juno Waves

et al. 2021

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“…Therefore, we anticipate an input rate of protons to the Jovian magnetosphere from Europa to be less than 0.1 kg s −1 . This value is at least an order of magnitude less input than the 2.5–13 kg s −1 required to sustain magnetospheric proton abundances inside 30 R J (Bodisch et al., 2017 ), further pointing to Jupiter as the likely source for magnetospheric protons, where Juno observations have shown proton outflow contributes at least 1–5 kg s −1 to the magnetosphere (Szalay et al., 2021 ).…”

Section: Discussionmentioning

confidence: 97%

Water‐Group Pickup Ions From Europa‐Genic Neutrals Orbiting Jupiter

Szalay

Smith

Zirnstein

et al. 2022

Geophysical Research Letters

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“…Quasi‐static electrostatic potentials associated with Jupiter's polar regions have been observed as large as 100's keV to ∼1 MeV (Clark et al., 2017 , 2020 ; Clark, Mauk, Haggerty, et al., 2017 ; Mauk et al., 2017 ). Near the main auroral emissions, quasi‐static potentials have also been observed to inject substantial quantities of protons into Jupiter's magnetosphere (Szalay et al., 2021 ), where ionospheric outflow is also required to transport ionospheric protons to these potential structures. While ionospheric outflow and some small degree of acceleration may be the source of the core ∼1 keV population, 100's keV quasistatic potentials would produce field‐aligned proton beams peaking around a characteristic energy.…”

Section: Discussionmentioning

confidence: 99%

“…Since arriving at Jupiter, Juno has directly sampled the fields and particles connected to the polar cap, while also collecting infrared and ultraviolet (UV) images of these regions. When magnetically connected equatorward of the polar caps, Juno observed diverse ion and electron populations associated with both ionospheric and Io‐genic plasma sources (Allegrini et al., 2017 ; Clark et al., 2018 ; Mauk et al., 2017 , 2018 ; Szalay et al., 2017 , 2021 ; Valek et al., 2019 ). Energetic ion conics, likely due to perpendicular heating via wave‐particle coupling, were observed just poleward of the main emissions (Clark, Mauk, Paranicas, et al., 2017 ).…”

Section: Introductionmentioning

confidence: 99%

Closed Fluxtubes and Dispersive Proton Conics at Jupiter's Polar Cap

Szalay

Clark

Livadiotis

et al. 2022

Geophysical Research Letters

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The polar regions of Jupiter's magnetosphere are unlike those of any other planet explored by spacecraft with an internal magnetic field. Mercury (e.g., Anderson et al., 2010), Earth (e.g., Smith & Lockwood, 1996), and Saturn (e.g., Jasinski et al., 2014 all exhibit open magnetic topologies in their polar-most regions, where the solar wind is magnetically connected to each of these planets. Evidence for this solar wind connectivity has been found in magnetic field signatures associated with magnetopause transits (e.g., Gurnett et al., 2010) and direct observation of solar wind plasma composition and polar rain -field aligned solar wind strahl electrons that stream along the interconnected magnetic field toward the planet (Winningham & Heikkila, 1974).Jupiter's magnetosphere is internally driven by its strong, rapidly rotating magnetic field and Io's immense heavy ion plasma source. It likely has a fundamentally different magnetospheric interaction with the solar wind than the aforementioned planets ). Jupiter's intense auroral features are primarily driven by plasma processes throughout the magnetosphere and are an important diagnostic in understanding these complex processes (Delamere & Bagenal, 2010). These auroral features (e.g., Grodent, 2016) are typically categorized into: the oval-shaped main auroral emission, Galilean satellite footprint aurora, diffuse emissions equatorward of the main oval, and polar cap emissions poleward of the main oval (Figure 1). Polar cap emissions can exhibit rapid variations (e.g., Bonfond et al., 2016) and the mechanisms sustaining these emissions remain a mystery (e.g., Ebert et al., 2019). As the most poleward auroral features would map to the farthest distances from Jupiter, these auroral emissions have been used to diagnose Jupiter's solar wind interaction. Polar cap emissions have previously been interpreted to infer the presence of a Jovian cusp (Bunce et al., 2004). In contrast, a subsequent analysis interpreted these emissions to indicate a highly complex topological setup where the large majority of

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Proton Outflow Associated With Jupiter's Auroral Processes

Cited by 14 publications

References 48 publications

The High‐Latitude Extension of Jupiter's Io Torus: Electron Densities Measured by Juno Waves

The High‐Latitude Extension of Jupiter's Io Torus: Electron Densities Measured by Juno Waves

Water‐Group Pickup Ions From Europa‐Genic Neutrals Orbiting Jupiter

Closed Fluxtubes and Dispersive Proton Conics at Jupiter's Polar Cap

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