Analysis of Intense Z ‐Mode Emission Observed During the Cassini Proximal Orbits

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Similar to whistler mode chorus, Z‐mode emission is an efficient diffusive scatterer of electrons possibly resulting in resonant acceleration. We present results of a survey of both the low‐band (5 kHz) and for the first time the high‐band (20 kHz) intensity of these emissions, based on over 11 years of Cassini Radio and Plasma Wave Science instrument data including nine ring‐grazing orbits and two proximal orbits, which occurred at the end of the mission. We distinguish these emissions using density and polarization measurements and calculate the mean intensity as a function of frequency and spatial coordinates. We find that the average low‐band Z‐mode intensity peak is P0 ~7 × 10−8 nT2, while the high‐band peak is much lower at P0 ~10−9 nT2. The spatial distribution of intensity differs for each emission band implying different source regions and perhaps different source mechanisms.

Section: Parametric Fittingmentioning

confidence: 75%

Extended Survey of Saturn Z‐Mode Wave Intensity Through Cassini's Final Orbits

Menietti

Averkamp

et al. 2018

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“…Many of the proximal orbits had these dropout features near ±40° along Cassini's path. In some cases, other emissions created in remote locations would mask or obscure these features (see Figures S8 and S9 in the supporting information; Menietti et al, ). However, in the northern sunlit hemisphere, in 15 out of 22 proximal cases, the abrupt dropout feature was observed.…”

Section: Methodsmentioning

confidence: 99%

“…Geophysical Research Letters supporting information; Menietti et al, 2018). However, in the northern sunlit hemisphere, in 15 out of 22 proximal cases, the abrupt dropout feature was observed.…”

Section: 1029/2018gl078137mentioning

confidence: 97%

Saturn's Plasma Density Depletions Along Magnetic Field Lines Connected to the Main Rings

Farrell

Hadid

Kurth

et al. 2018

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We report on a set of clear and abrupt decreases in the high‐frequency boundary of whistler mode emissions detected by Cassini at high latitudes (about ±40°) during the low‐altitude proximal flybys of Saturn. These abrupt decreases or dropouts have start and stop locations that correspond to L shells at the edges of the A and B rings. Langmuir probe measurements can confirm, in some cases, that the abrupt decrease in the high‐frequency whistler mode boundary is associated with a corresponding abrupt electron density dropout over evacuated field lines connected to the A and B rings. Wideband data also reveal electron plasma oscillations and whistler mode cutoffs consistent with a low‐density plasma in the region. The observation of the electron density dropout along ring‐connecting field lines suggests that strong ambipolar forces are operating, drawing cold ionospheric ions outward to fill the flux tubes. There is an analog with the refilling of flux tubes in the terrestrial plasmasphere. We suggest that the ring‐connected electron density dropouts observed between 1.1 and 1.3 Rs are connected to the low‐density ring plasma cavity observed overtop the A and B rings during the 2004 Saturn orbital insertion pass.

“…This trajectory granted large latitudinal coverage as well as unrivaled proximity to the giant planet over an orbital period of ~6.5 days. First in situ measurements of the ionosphere have revealed intense plasma waves and large variability in electron density of up to 2 orders of magnitude as well as a north‐south asymmetry attributed to the shadow cast by Saturn's A and B rings (Menietti et al, ; Persoon et al, ; Sulaiman et al, , this issue; Wahlund et al, ).…”

Section: Introductionmentioning

confidence: 99%

Enceladus Auroral Hiss Emissions During Cassini's Grand Finale

Sulaiman

Kurth

Hospodarsky

et al. 2018

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Cassini's Radio and Plasma Wave Science (RPWS) instrument detected intense auroral hiss emissions during one of its perikrone passes of the Grand Finale orbits. The emissions were detected when Cassini traversed a flux tube connected to Enceladus' orbit (L‐shell = 4) and at a time when both the spacecraft and the icy moon were in similar longitudes. Previous observations of auroral hiss related to Enceladus were made only during close flybys and here we present the first observation of such emissions close to Saturn. Further, ray‐tracing analysis shows the source location at a latitude of 63°, in excellent agreement with earlier UVIS observations of Enceladus' auroral footprint by Pryor et al. (2011, https://doi.org/10.1038/nature09928). The detection has been afforded exclusively by the Grand Finale phase, which enabled sampling of Enceladus' high‐latitude flux tube near Saturn. This result provides new insight into the spatial extent of the electrodynamic interaction between Saturn and Enceladus.