Abstract
Abstract The present study combines Radio and Plasma Wave Science/Langmuir Probe and Ion and Neutral Mass Spectrometer data from Cassini’s last four orbits into Saturn’s lower ionosphere to constrain the effective recombination coefficient α 300 from measured number densities and electron temperatures at a reference electron temperature of 300 K. Previous studies have shown an influx of ring material causes a state of electron depletion due to grain charging, which will subsequently affect the ionospheric chemistry. The requirement to take grain charging into account limits the derivation of α 300 to upper limits. Assuming photochemical equilibrium and using an established method to calculate the electron production rate, we derive upper limits for α 300 of ≲ 3 × 10−7 cm3 s−1 for altitudes below 2000 km. This suggests that Saturn’s ionospheric positive ions are dominated by species with low recombination rate coefficients like HCO+. An ionosphere dominated by water group ions or complex hydrocarbons, as previously suggested, is incompatible with this result, as these species have recombination rate coefficients > 5 × 10−7 cm3 s−1 at an electron temperature of 300 K.
Highlights
The joint NASA/ESA/ASI Cassini–Huygens mission surveyed the Kronian system in great detail after arriving at Saturn in 2004, providing unprecedented insight into the lower ionospheric altitudes during the so-called Grand Finale
The upper limits for α300 derived from measured data for orbit 292 are shown in Figure 4, split into the inbound and outbound parts
For orbits 290, 291, and 293 we consider only the inbound parts and use modeled H+2 number densities, while all other data are measured by Radio and Plasma Wave Science (RPWS)/Langmuir probe (LP) or Ion and Neutral Mass Spectrometer (INMS)
Summary
The joint NASA/ESA/ASI Cassini–Huygens mission surveyed the Kronian system in great detail after arriving at Saturn in 2004, providing unprecedented insight into the lower ionospheric altitudes during the so-called Grand Finale. The onboard Radio and Plasma Wave Science (RPWS) instrument, including the Langmuir probe (LP), measured electron and total ion number densities (ne and ni), as well as electron temperatures Number densities of H2 well as light positive ions (H+, and other neutral H+2 , H+3 ), were measured by the Ion and Neutral Mass Spectrometer E.g., Waite et al 2018). The analysis of these data sets revealed a multitude of unexpected phenomena, such as prominent levels of electron depletion (ne = ni) at low altitudes. Assuming quasi-neutrality, a negatively charged dust component could act as the negative charge carrier alongside free electrons (Morooka et al 2019)
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call