Jovian electrons in the inner heliosphere

Vogt, Adrian; Heber, Bernd; Kopp, A.; Potgieter, M. S.; Strauss, R. D.

doi:10.1051/0004-6361/201731736

Cited by 24 publications

(25 citation statements)

References 74 publications

(89 reference statements)

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“…As another possible application, it might be worth considering in a future study whether the escape of relativistic electrons, with their intermediate-sized gyroradii, might also be governed by the processes described in this paper. Such electrons are relatively common in the interplanetary environment as reviewed by Vogt et al (2018). While electrons in the tens to hundreds of kiloelectron volts have gyroradii much smaller than the protons in the same range of energies, electrons at energies between 8 and 13 MeV have gyroradii comparable in size to protons in the 50-to 100-keV range.…”

Section: General Applicabilitymentioning

confidence: 99%

Investigation of Mass‐/Charge‐Dependent Escape of Energetic Ions Across the Magnetopauses of Earth and Jupiter

et al. 2019

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We present a continuing investigation of mass‐/charge‐dependent interactions between energetic ions (greater than tens of kiloelectron volts) and planetary magnetopauses and of the escape of the ions across the boundary. Previous studies at Earth using Magnetospheric Multiscale mission data are refined and advanced showing profound behavior differences between light (H, He) and singly charged heavy ions (O+). We highlight a distinctive feature of oxygen ions: an angular distribution bifurcation providing clear indication of entrainment along the magnetopause in Speiser‐like orbits during relatively stable magnetic conditions. This signature, interpreted using a simple kinetic model, suggests that these ions tend to be carried substantial distances along the boundary (even with boundary‐normal magnetic fields) in a fashion that impedes their full dayside escape. While large fluctuations and waves can likely sometimes disrupt the observed ordering, the following picture emerges. Energetic particles with gyroradii much smaller than the magnetopause thickness (e.g., electrons and absent boundary‐normal magnetic fields) and ions with gyroradii much larger than the thickness (e.g., O+) are impeded from fully escaping across the boundary. However, energetic ions with intermediate‐sized gyroradii commensurate with the thickness (e.g., H+, He++, and O6+) can be effectively scattered within the boundary causing them to escape much more readily, with and without boundary‐normal fields. This picture is supported by observations from the Juno spacecraft at the near‐dawn meridian side of Jupiter's magnetopause. There it is observed that energetic electrons and heavy ions are more strongly contained by the magnetopause than are the energetic protons and helium ions.

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Section: General Applicabilitymentioning

confidence: 99%

Investigation of Mass‐/Charge‐Dependent Escape of Energetic Ions Across the Magnetopauses of Earth and Jupiter

et al. 2019

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“…Critical for evaluating the presence of JCRPs are observations near and within Jupiter's magnetosphere, which can inform us about the efficiency proton and ion acceleration in that system and what the spectrum of the particles escaping into the heliosphere is. The search for very high energy protons and heavy ions through measurements near Jupiter by Voyager (Krimigis et al 1977;Stilwell et al 1979), Ulysses (Simpson et al 1992), Juno (Mauk et al 2013;Becker et al 2017), and Galileo (Garrard et al 1992;Williams et al 1992) could constrain the spectrum of possible JCRPs escaping from the planet's magnetosphere and allow for a comparison with observations at different heliocentric distances, similar to Vogt et al (2018). Within the Jovian magnetosphere, protons and ions between several MeV n -1 and up to ∼100 MeV n -1 have been observed in the planet's radiation belts, at an acceleration region in Jupiter's middle and outer magnetosphere, or on highlatitude field lines possibly mapping to the auroral region (Zhang et al 1995;Fischer et al 1996;Anglin et al 1997;Selesnick et al (2001).…”

Section: Tablementioning

confidence: 99%

“…Relativistic electrons from Jupiter that have been observed throughout the inner heliosphere are the most characteristic example for this case (Teegarden et al 1974;Krimigis et al 1975;Ferreira et al 2003;Heber et al 2007). When a spacecraft is connected to Jupiter through interplanetary magnetic field (IMF) lines, fluxes of <30 MeV Jovian electrons dominate over those of GCR electrons (Nndanganeni & Potgieter 2018;Vogt et al 2018), even though Jupiter is a point source in the heliosphere. Energetic ions of planetary origin and with subrelativistic energies (<5 MeV) have been observed in the heliosphere upstream of magnetospheric bow shocks (Krimigis et al 2009) or, in the case of Jupiter, within about 1 au of its magnetosphere (Marhavilas et al 2001;Anagnostopoulos et al 2009).…”

Section: Introductionmentioning

confidence: 99%

Jovian Cosmic-Ray Protons in the Heliosphere: Constraints by Cassini Observations

Roussos

Krupp

Dialynas

et al. 2019

ApJ

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Measurements of >82 MeV Galactic cosmic-ray (GCR) protons at Earth indicate that they may be mixed with protons that leak into the heliosphere from Jupiter's magnetosphere (Jovian cosmic-ray protons (JCRPs)). A ∼400 day periodicity in these proton fluxes, which is similar to the synodic period between Jupiter and Earth, and an excess proton flux observed when Jupiter and Earth can be connected through the interplanetary magnetic field were the basis for this claim. Using nearly 13 yr of GCR measurements at Saturn with Cassini's Magnetosphere Imaging Instrument, we show that the ∼400 day periodicity is also present in 100 MeV protons at ∼9.6 au, although the synodic period between Saturn and Jupiter is ∼20 yr. We also find that the features responsible for this periodicity were convected from 1 au to Saturn's distance with the solar wind velocity. Their origin is therefore heliospheric, not Jovian. We attribute these features to quasi-biennial oscillations, observed in the solar magnetic field and various heliospheric indices. This finding indicates that fluxes of JCRPs at 1 au, if present, are considerably overestimated, because the signal originally attributed to them represents the amplitude of the ∼400 day periodic GCR oscillation. This oscillation has to be subtracted before the resulting proton GCR flux residuals are analyzed in the context of a possible Jovian source. A confirmation of the presence of JCRPs over extended regions in the heliosphere and a constraint on their fractional abundance in GCR spectra may therefore require further validation and analysis, and several options are proposed for this purpose.

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“…From previous modulation studies, the Jovian electron contribution at these low energies far outweighs that of galactic electrons (see, e.g., Ferreira et al 2001aFerreira et al , 2001bStrauss et al 2011). The sensitivity of computed low-energy CR electron intensities to the choice of λ out suggests that such a physics-first approach, should a Jovian source be considered, could provide more insight as to possible values for this quantity, as well as providing extra insight into the behavior of other turbulence and large-scale quantities affecting the transport of these particles such as the dissipation range onset wavenumber or the HMF geometry, which may not be readily discernible using currently existing spacecraft observations (see, e.g., Engelbrecht & Burger 2010;Sternal et al 2011;Strauss et al 2011;Engelbrecht & Burger 2013b;Vogt et al 2018) by careful comparisons of model outputs with observations, while also providing a more nuanced understanding of the transport of CRs in the heliosphere than is possible using ad hoc formulations for diffusion coefficients. This will be the subject of future studies.…”

Section: Discussionmentioning

confidence: 99%

“…Overall, however, the intensities calculated with the model presented in this study remain close to the Adriani et al (2011) observations at high energies, follow the trend of observations at intermediate energies (albeit at different levels of modulation), and are only significantly below observations at the lowest energies. This last point, however, is simply due to the fact that observations below ∼100MeV are dominated by a Jovian electron component (see, e.g., Ferreira et al 2001a;Vogt et al 2018), which is not taken into account in this study. The top panel shows differential intensities calculated for periods of positive (qA<0, blue lines) and negative (qA>0, red lines) magnetic polarity assuming that λ out corresponds to the observed island sizes (dashed lines) and the Adhikari et al (2017a;dotted lines) and Engelbrecht & Burger (2013a; solid lines) assumptions for λ out .…”

Section: The Effects Of the 2d Outerscale On Galactic Cr Electron Modmentioning

confidence: 91%

The Implications of Simple Estimates of the 2D Outerscale Based on Measurements of Magnetic Islands for the Modulation of Galactic Cosmic-Ray Electrons

Engelbrecht

2019

ApJ

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The behavior of the 2D turbulence power spectrum at the lowest wavenumbers has a significant effect on the perpendicular diffusion coefficients of charged particles in the heliosphere derived from various scattering theories, and subsequently used to model the transport of cosmic rays (CRs) and solar energetic particles. In this regard, the lengthscale at which the energy-containing range begins, as opposed to that at which the inertial range commences, is of particular interest. This 2D outerscale has, however, never before been directly observed. Recently, direct measurements of magnetic islands in the solar wind have been reported by various authors. Assuming that these may provide an estimate of the 2D ultrascale, the direct calculation of the 2D outerscale becomes possible, should an observationally motivated form for the 2D turbulence power spectrum be employed. This study presents the results of such a calculation and provides comparisons of these with previous estimates of the 2D outerscale. Furthermore, the sensitivity of galactic CR electron intensities, calculated using a 3D ab initio CR modulation model, is demonstrated, and conclusions are drawn therefrom.

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Jovian electrons in the inner heliosphere

Cited by 24 publications

References 74 publications

Investigation of Mass‐/Charge‐Dependent Escape of Energetic Ions Across the Magnetopauses of Earth and Jupiter

Investigation of Mass‐/Charge‐Dependent Escape of Energetic Ions Across the Magnetopauses of Earth and Jupiter

Jovian Cosmic-Ray Protons in the Heliosphere: Constraints by Cassini Observations

The Implications of Simple Estimates of the 2D Outerscale Based on Measurements of Magnetic Islands for the Modulation of Galactic Cosmic-Ray Electrons

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