Survey of whistler mode chorus intensity at Jupiter

Menietti, J. D.; Groene, J. B.; Averkamp, T. F.; Horne, Richard B.; Woodfield, E. E.; Shprits, Y. Y.; Pich, M. de Soria-Santacruz; Gurnett, D. A.

doi:10.1002/2016ja022969

Cited by 28 publications

(58 citation statements)

References 38 publications

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“…An alternative acceleration process would have been energy diffusion from interaction with whistler waves (Woodfield et al, ). Since the intensity of these waves is small for L > 20 (Menietti et al, ), it is maybe not surprising that acceleration occurs through adiabatic transport instead.…”

Section: Discussionmentioning

confidence: 99%

Electron Acceleration to MeV Energies at Jupiter and Saturn

et al. 2018

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The radiation belts and magnetospheres of Jupiter and Saturn show significant intensities of relativistic electrons with energies up to tens of megaelectronvolts (MeV). To date, the question on how the electrons reach such high energies is not fully answered. This is largely due to the lack of high‐quality electron spectra in the MeV energy range that models could be fit to. We reprocess data throughout the Galileo orbiter mission in order to derive Jupiter's electron spectra up to tens of MeV. In the case of Saturn, the spectra from the Cassini orbiter are readily available and we provide a systematic analysis aiming to study their acceleration mechanisms. Our analysis focuses on the magnetospheres of these planets, at distances of L > 20 and L > 4 for Jupiter and Saturn, respectively, where electron intensities are not yet at radiation belt levels. We find no support that MeV electrons are dominantly accelerated by wave‐particle interactions in the magnetospheres of both planets at these distances. Instead, electron acceleration is consistent with adiabatic transport. While this is a common assumption, confirmation of this fact is important since many studies on sources, losses, and transport of energetic particles rely on it. Adiabatic heating can be driven through various radial transport mechanisms, for example, injections driven by the interchange instability or radial diffusion. We cannot distinguish these processes at Saturn with our technique. For Jupiter, we suggest that the dominating acceleration process is radial diffusion because injections are never observed at MeV energies.

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Section: Discussionmentioning

confidence: 99%

Electron Acceleration to MeV Energies at Jupiter and Saturn

et al. 2018

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“…In summary, the present study provides direct evidence that diffuse auroral emissions at Jupiter are produced by electron precipitation covering a broad range of energy (0.1–700 keV) due to efficient pitch angle scattering. Although whistler mode waves have been suggested to cause pitch angle scattering into the loss cone (Bhattacharya et al, , ; Bolton et al, ; Mauk et al, ; Xiao et al, ), Galileo wave observations showed that these whistler mode emissions are commonly detected near the magnetic equator in the Jovian magnetosphere over 8–15 R J (Menietti et al, , ). Therefore, these whistler mode waves potentially responsible for causing diffuse auroral electron precipitations were not detected by Juno in the polar region during PJ1.…”

Section: Summary and Discussionmentioning

confidence: 99%

“…However, in the diffuse auroral region, only weaker emissions were detected mostly below the proton cyclotron frequency. Whistler mode waves, which are suggested to cause pitch angle scattering of diffuse auroral electrons (Bhattacharya et al, , ; Bolton et al, ; Mauk et al, ; Xiao et al, ), are probably located near the magnetic equator in the Jupiter's middle magnetosphere (Bhattacharya et al, ; Menietti et al, ) and thus were not detected at this high latitude. It is interesting to note that weak electromagnetic emissions above the proton cyclotron frequency exhibited a sharp cutoff at M shell ~6, near the trajectory of Io.…”

Section: Juno Observation Of Auroral Emissions and Energetic Electronsmentioning

confidence: 99%

Understanding the Origin of Jupiter's Diffuse Aurora Using Juno's First Perijove Observations

Thorne

Zhang

et al. 2017

Geophysical Research Letters

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Juno observed the low‐altitude polar region during perijove 1 on 27 August 2016 for the first time. Auroral intensity and false‐color maps from the Ultraviolet Spectrograph (UVS) instrument show extensive diffuse aurora observed equatorward of the main auroral oval. Juno passed over the diffuse auroral region near the System III longitude of 120°–150° (90°–120°) in the northern (southern) hemisphere. In the region where these diffuse auroral emissions were observed, the Jupiter Energetic Particle Detector Instrument (JEDI) and Jovian Auroral Distributions Experiment (JADE) instruments measured nearly full loss cone distributions for the downward going electrons over energies of 0.1–700 keV but very few upward going electrons. The false‐color maps from UVS indicate more energetic electron precipitation at lower latitudes than less energetic electron precipitation, consistent with observations of precipitating electrons measured by JEDI and JADE. The comparison between particle and aurora measurements provides first direct evidence that these precipitating energetic electrons are mainly responsible for the diffuse auroral emissions at Jupiter.

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“…Readers are referred to the study of Xiao FL et al (2009) for details of the numerical scheme and method. Figure 1 shows the latitudinal dependence of B w over L J = 6-14 for upper band and lower band chorus, respectively, following the study of Menietti et al (2016). Clearly, in the Jovian radiation belts the typical wave amplitude is < 20 pT for lower band chorus (LBC) and < 2 pT for upper band chorus (UBC).…”

Section: (8)mentioning

confidence: 99%

“…A later study, Shprits et al () confirmed that interactions with whistler waves cause significant local acceleration of electrons at Jupiter, and indicated that the wave latitudinal distribution has a determining role in the dynamics of energetic electrons. Menietti et al () obtained a quantized distribution of chorus magnetic field intensity for use in stochastic modeling efforts, suggesting that chorus induced wave‐particle interactions at Jupiter may play an even greater role than earlier proposed. De Soria‐Santacruz et al () further clarified that the shape of the electron phase space density and the latitudinal extent of the chorus waves are important for both the acceleration and loss of Jovian radiation belt electrons.…”

Section: Introductionmentioning

confidence: 98%

Importance of electron distribution profiles to chorus wave driven evolution of Jovian radiation belt electrons

Huang

et al. 2018

Earth and Planetary Physics

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Wave‐particle interactions triggered by whistler‐mode chorus waves are an important contributor to the Jovian radiation belt electron dynamics. While the sensitivity of chorus‐driven electron scattering to the ambient magnetospheric and wave parameters has been investigated, there is rather limited understanding regarding the extent to which the dynamic evolution of Jovian radiation belt electrons, under the impact of chorus wave scattering, depends on the electron distribution profiles. We adopt a group of reasonable initial conditions based upon the available observations and models for quantitative analyses. We find that inclusion of pitch angle variation in initial conditions can result in increased electron losses at lower pitch angles and substantially modify the pitch angle evolution profiles of > ~500 keV electrons, while variations of electron energy spectrum tend to modify the evolution primarily of 1 MeV and 5 MeV electrons. Our results explicitly demonstrate the importance to the radiation belt electron dynamics in the Jovian magnetosphere of the initial shape of the electron phase space density, and indicate the extent to which variations in electron energy spectrum and pitch angle distribution can contribute to the evolution of Jovian radiation belt electrons caused by chorus wave scattering.

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Survey of whistler mode chorus intensity at Jupiter

Cited by 28 publications

References 38 publications

Electron Acceleration to MeV Energies at Jupiter and Saturn

Electron Acceleration to MeV Energies at Jupiter and Saturn

Understanding the Origin of Jupiter's Diffuse Aurora Using Juno's First Perijove Observations

Importance of electron distribution profiles to chorus wave driven evolution of Jovian radiation belt electrons

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