Juno Constraints on the Formation of Jupiter's Magnetospheric Cushion Region

Gershman, D. J.; DiBraccio, G. A.; Connerney, J. E. P.; Bagenal, F.; Kurth, W. S.; Hospodarsky, G. B.; Spalsbury, L.; Clark, G.; Ebert, R. W.; Wilson, R.; Levin, S. M.; Bolton, S. J.

doi:10.1029/2018gl079118

Cited by 7 publications

(13 citation statements)

References 50 publications

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“…This most likely means that during our observations, Jupiter is north of the solar current sheet more often than south of it (since the solar dipole is pointing northwards during this solar cycle). As mentioned by Gershman et al (2018), Juno's orbital period is close to double the solar rotation period. So from orbit to orbit, Juno will see similar solar wind conditions, like magnetic field direction, while in the magnetosheath.…”

Section: 1029/2019ja027382mentioning

confidence: 77%

Survey of Jupiter's Dawn Magnetosheath Using Juno

et al. 2019

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The Juno spacecraft crossed Jupiter's bow shock and into the magnetosheath on 24 June 2016.It then went into 53-day polar orbits with its apojoves at 113 Jovian radii on Jupiter's dawn side. These orbits have given us a unique opportunity to survey Jupiter's dawn magnetosheath. Using data from the Jovian Auroral Distributions Experiment, the Magnetic Field Investigation, and the Waves Investigation, we have identified 91 magnetosheath crossings for a total of 48.2 days of data. We present the statistical properties of the magnetosheath plasma, including density, velocity, magnetic field strength, temperature, plasma beta, pressures, and Mach numbers. We then show correlations between these various parameters. We confirm the rotation of the magnetic field to align with Jupiter's spin axis and find that this rotation correlates with several of the plasma properties, including magnetic field strength and plasma flow velocity. Finally, we discuss how these results can affect magnetic reconnection and the Kelvin-Helmholtz instability at Jupiter's dawn magnetopause boundary. Key Points:• Juno's unique orbit has allowed a survey of Jupiter's dawn magnetosheath • Jupiter's magnetosheath is very dynamic, and the plasma properties span many orders of magnitude • The enhancement of B Z in Jupiter's magnetosheath is correlated with magnetic field strength and flow speed Supporting Information:• Supporting Information S1

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Section: 1029/2019ja027382mentioning

confidence: 77%

Survey of Jupiter's Dawn Magnetosheath Using Juno

et al. 2019

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“…Due to the flapping motion of the magnetodisk, Juno periodically crosses the equatorial plane (local B minimum) and reaches the plasma sheet edge (local B maximum). This plasma sheet edge (presumably the PSBL) is characterized by (1) weak thermal electron fluxes, (2) field‐aligned pitch‐angle distributions of high‐energy electrons, and (3) intense wave electric field bursts on top of the continuum radiation (tracking the density variations and indicating that Juno is on closed field lines; see, e.g., Hospodarsky et al., 2017; Gershman et al., 2018). In this study, we collect statistics of Juno observations during such crossings of the magnetodisk.…”

Section: Methodsmentioning

confidence: 99%

Plasma Sheet Boundary Layer in Jupiter's Magnetodisk as Observed by Juno

Zhang

Artemyev

et al. 2020

JGR Space Physics

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The Juno spacecraft has been orbiting Jupiter for the past 3 years. During this interval, Juno has collected large datasets of plasma, magnetic field, and wave measurements in Jupiter's magnetosphere. In this study, we conduct statistics on the plasma and wave characteristics in Jupiter's magnetodisk (nightside magnetosphere beyond 20 Jupiter radii, RJ). Distributions of electron fluxes and waves in the magnetodisk exhibit different characteristics in two regions: the plasma sheet with dense plasma and weak wave intensity and the plasma sheet boundary layer (PSBL) occupied by strong waves and rarefied plasma. We discuss that these waves can be generated by field‐aligned high‐energy electrons in the PSBL. We further compare plasma and wave properties in the PSBL of Jupiter's magnetodisk with the PSBL in Earth's magnetotail. This comparison suggests that the PSBL in Jupiter's magnetodisk may be formed by transient magnetic reconnection in the Jovian magnetosphere. The dawn‐dusk asymmetry of the PSBL properties further supports this scenario: the PSBL is more pronounced in the dawn flank of Jupiter's magnetodisk, where magnetic reconnection is predicted to occur by models of the rotation‐dominated magnetosphere. We further discuss properties of the Jovian PSBL and implications on magnetic reconnection in Jupiter's magnetosphere.

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“…Therefore, the return flow of depleted electrons at dawn found in this study may carry energetic plasma not observable by ELS. Further effort and investigations are required to make a more conclusive statement on this topic at Saturn (and it seems, also at Jupiter: Gershman et al, ).…”

Section: Resultsmentioning

confidence: 99%

“…This region also exhibits dipolar configurations of the magnetospheric field and magnetic nulls, which arise from instabilities that form at the outer edge of the plasma sheet. Most recently, there is evidence that the concept of the cushion region may need to be reassessed because the Juno spacecraft did not observe a persistent cushion region on the dawn flank (Gershman et al, 2018). Went et al (2011) compared observations from Jupiter (with the Ulysses spacecraft) and Saturn (Cassini) and concluded that Saturn lacked a cushion region of quasi-dipolar flux tubes.…”

Section: Equatorial Plane-lt Asymmetrymentioning

confidence: 99%

Saturn's Open‐Closed Field Line Boundary: A Cassini Electron Survey at Saturn's Magnetosphere

et al. 2019

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We investigate the average configuration and structure of Saturn's magnetosphere in the nightside equatorial and high-latitude regions. Electron data from the Cassini Plasma Spectrometer's Electron Spectrometer (CAPS-ELS) is processed to produce a signal-to-noise ratio for the entire CAPS-ELS time of operation at Saturn's magnetosphere. We investigate where the signal-to-noise ratio falls below 1 to identify regions in the magnetosphere where there is a significant depletion in the electron content. In the nightside equatorial region, we use this to find that the most planetward reconnection x-line location is at 20-25 R S downtail from the planet in the midnight to dawn sector. We also find an equatorial dawn-dusk asymmetry at a radial distance of >20 R S , which may indicate the presence of plasma-depleted flux tubes returning to the dayside after reconnection in the tail. Furthermore, we find that the high-latitude magnetosphere is predominantly in a state of constant plasma depletion and located on open field lines. We map the region of high-latitude magnetosphere that is depleted of electrons to the polar cap to estimate the size and open flux content within the polar caps. The mean open flux content for the northern and southern polar caps are found to be 25 ± 5 and 32 ± 5 GWb, respectively. The average location of the open-closed field boundary is found at invariant colatitudes of 12.7 ± 0.6°and 14.5 ± 0.6°. The northern boundary is modulated by planetary period oscillations more than the southern boundary.

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Juno Constraints on the Formation of Jupiter's Magnetospheric Cushion Region

Cited by 7 publications

References 50 publications

Survey of Jupiter's Dawn Magnetosheath Using Juno

Survey of Jupiter's Dawn Magnetosheath Using Juno

Plasma Sheet Boundary Layer in Jupiter's Magnetodisk as Observed by Juno

Saturn's Open‐Closed Field Line Boundary: A Cassini Electron Survey at Saturn's Magnetosphere

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