Determining the Beaming of Io Decametric Emissions: A Remote Diagnostic to Probe the Io‐Jupiter Interaction

Lamy, Laurent; Colomban, Lucas; Zarka, Philippe; Prangé, Renée; Marques, M. S.; Louis, Corentin; Kurth, W. S.; Cecconi, Baptiste; Girard, Julien N.; Grießmeier, J.-M.; Yerin, S. N.

doi:10.1029/2021ja030160

Cited by 8 publications

(13 citation statements)

References 53 publications

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“…For instance, comparing in more details the simulations that account for the lead angle and refractions effects (Figure 8c) with the circularly polarized radio emission from RPWS indicates that the early part of the radio emission arc (from 22:00:00 to 22:15:00) are better reproduced with electrons with lower energies, that is, 5 keV, while the center and end of the arc are better reproduced with electrons with energies ranging from 10 to 15 keV. It is worth noting here that Lamy et al (2022) showed that, in the case of Io, the electrons energy derived from radio emission analysis is variable as a function of the moon longitude. It is not surprising here to observe that in order to reproduce the arc in the time-frequency plane, the energy of the electrons must vary with time (i.e., the longitude of the moon).…”

Section: Application To Modeling Of the Moon-induced Decametric Emissionmentioning

confidence: 74%

“…It is worth noting here that Lamy et al. (2022) showed that, in the case of Io, the electrons energy derived from radio emission analysis is variable as a function of the moon longitude. It is not surprising here to observe that in order to reproduce the arc in the time‐frequency plane, the energy of the electrons must vary with time ( i.e., the longitude of the moon).…”

Section: Application To Modeling Of the Moon‐induced Decametric Emissionmentioning

confidence: 88%

“…Because the directionality of these radio emissions depend both on the electron energy and the lead angle, this may lead to situations where non‐unique solutions exist, in order to reproduce the observed decametric radio arcs. The knowledge of the active field line (where the radio emission sources are located) and thus the lead angle, constitutes one of the main sources of uncertainty in determining the electron energy responsible for the radio emission (Hess, Pétin, et al., 2010; Lamy et al., 2022). Previous estimate of the absolute lead angle values were not accurate enough mostly because of the uncertainty in the magnetic field models as well as the uncertainties in the Europa and Ganymede measured footprint positions from HST (Hess, Pétin, et al., 2010), leading to non‐physical cases with negative lead‐angle.…”

Section: Application To Modeling Of the Moon‐induced Decametric Emissionmentioning

confidence: 99%

“…The knowledge of the lead angle is also important for the interpretation of the moon‐induced decametric emissions (e.g., Hess, Pétin, et al., 2010; Louis et al., 2019; Lamy et al., 2022; Marques et al., 2017). This section illustrates the added benefit from the equatorial lead angle knowledge in a case related to the interpretion of the Ganymede‐induced decametric radio emission.…”

Section: Application To Modeling Of the Moon‐induced Decametric Emissionmentioning

confidence: 99%

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The Io, Europa, and Ganymede Auroral Footprints at Jupiter in the Ultraviolet: Positions and Equatorial Lead Angles

et al. 2023

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Jupiter's satellite auroral footprints are a consequence of the interaction between the Jovian magnetic field with co‐rotating iogenic plasma and the Galilean moons. The disturbances created near the moons propagate as Alfvén waves along the magnetic field lines. The position of the moons is therefore “Alfvénically” connected to their respective auroral footprint. The angular separation from the instantaneous magnetic footprint can be estimated by the so‐called lead angle. That lead angle varies periodically as a function of orbital longitude, since the time for the Alfvén waves to reach the Jovian ionosphere varies accordingly. Using spectral images of the Main Alfvén Wing auroral spots collected by Juno‐UVS during the first 43 orbits, this work provides the first empirical model of the Io, Europa, and Ganymede equatorial lead angles for the northern and southern hemispheres. Alfvén travel times between the three innermost Galilean moons to Jupiter's northern and southern hemispheres are estimated from the lead angle measurements. We also demonstrate the accuracy of the mapping from the Juno magnetic field reference model (JRM33) at the completion of the prime mission for M‐shells extending to at least 15 RJ. Finally, we shows how the added knowledge of the lead angle can improve the interpretation of the moon‐induced decametric emissions.

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Section: Application To Modeling Of the Moon-induced Decametric Emissionmentioning

confidence: 74%

Section: Application To Modeling Of the Moon‐induced Decametric Emissionmentioning

confidence: 88%

Section: Application To Modeling Of the Moon‐induced Decametric Emissionmentioning

confidence: 99%

Section: Application To Modeling Of the Moon‐induced Decametric Emissionmentioning

confidence: 99%

See 2 more Smart Citations

The Io, Europa, and Ganymede Auroral Footprints at Jupiter in the Ultraviolet: Positions and Equatorial Lead Angles

et al. 2023

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“…The radio emission from the exomoon interaction could also be a time variable similar to the variability seen in the Jupiter-Io emission. Furthermore, the emission due to the interaction between Io and Jupiter is also highly beamed (e.g., Queinnec & Zarka 1998;Zarka et al 2004;Ray & Hess 2008;Lamy et al 2022). Similar beaming is expected from exomoon-exoplanet interactions.…”

Section: Time Variable and Beamed Emissionmentioning

confidence: 75%

Radio-loud Exoplanet-exomoon Survey: GMRT Search for Electron Cyclotron Maser Emission

Narang

Oza

Hakim

et al. 2022

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We conducted the first dedicated search for signatures of exoplanet–exomoon interactions using the Giant Metrewave Radio Telescope (GMRT) as part of the radio-loud exoplanet-exomoon survey. Due to stellar tidal heating, irradiation, and subsequent atmospheric escape, candidate “exo-Io” systems are expected to emit up to 106 times more plasma flux than the Jupiter-Io DC circuit. This can induce detectable radio emission from the exoplanet-exomoon system. We analyze three “exo-Io” candidate stars: WASP-49, HAT-P 12, and HD 189733. We perform 12 hr phase-curve observations of WASP-49b at 400 MHz during primary & secondary transit, as well as first & third quadratures achieving a 3σ upper limit of 0.18 mJy beam−1 averaged over four days. HAT-P 12 was observed with GMRT at 150 and 325 MHz. We further analyzed the archival data of HD 189733 at 325 MHz. No emission was detected from the three systems. However, we place strong upper limits on radio flux density. Given that most exo-Io candidates orbit hot Saturns, we encourage more multiwavelength searches (in particular low frequencies) to span the lower range of exoplanet B-field strengths constrained here.

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Source of Radio Emissions Induced by the Galilean Moons Io, Europa and Ganymede: In Situ Measurements by Juno

Louis,

Louarn,

Collet

et al. 2023

JGR Space Physics

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At Jupiter, part of the auroral radio emissions are induced by the Galilean moons Io, Europa and Ganymede. Until now, except for Ganymede, they have been only remotely detected, using ground–based radio–telescopes or electric antennas aboard spacecraft. The polar trajectory of the Juno orbiter allows the spacecraft to cross the range of magnetic flux tubes which sustain the various Jupiter–satellite interactions, and in turn to sample in situ the associated radio emission regions. In this study, we focus on the detection and the characterization of radio sources associated with Io, Europa and Ganymede. Using electric wave measurements or radio observations (Juno/Waves), in situ electron measurements (Juno/JADE–E), and magnetic field measurements (Juno/MAG) we demonstrate that the Cyclotron Maser Instability (CMI) driven by a loss–cone electron distribution function is responsible for the encountered radio sources. We confirmed that radio emissions are associated with Main (MAW) or Reflected Alfvén Wing (RAW), but also show that for Europa and Ganymede, induced radio emissions are associated with Transhemispheric Electron Beam (TEB). For each traversed radio source, we determine the latitudinal extension, the CMI–resonant electron energy, and the bandwidth of the emission. We show that the presence of Alfvén perturbations and downward field–aligned currents are necessary for the radio emissions to be amplified.

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Determining the Beaming of Io Decametric Emissions: A Remote Diagnostic to Probe the Io‐Jupiter Interaction

Cited by 8 publications

References 53 publications

The Io, Europa, and Ganymede Auroral Footprints at Jupiter in the Ultraviolet: Positions and Equatorial Lead Angles

The Io, Europa, and Ganymede Auroral Footprints at Jupiter in the Ultraviolet: Positions and Equatorial Lead Angles

Radio-loud Exoplanet-exomoon Survey: GMRT Search for Electron Cyclotron Maser Emission

Source of Radio Emissions Induced by the Galilean Moons Io, Europa and Ganymede: In Situ Measurements by Juno

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