The effect of field-aligned currents and centrifugal forces on ionospheric outflow at Saturn

Martin, Carley and Ray, Licia C and Felici, M. and Constable, DA and Lorch, Chris and Kinrade, Joe and Gray, Rebecca (2020) The effect of field-aligned currents and centrifugal forces on ionospheric outflow at Saturn. Journal of Geophysical Research: Space Physics, 125 (7): e2019JA027. ISSN 2169-9402

Text (MartinEtAl_2020_SaturnIonosphericOutflow_accepted)
combinedManuscript.pdf - Accepted Version
Available under License Creative Commons Attribution-NonCommercial.
Download (420kB)

Abstract

Ionospheric outflow is driven by an ambipolar electric field induced due to the separation of electrons and ions in a gravitational field when equilibrium along a magnetic field line is lost. A model of ionospheric outflow at Saturn was developed using transport equations to estimate the number of charged particles that flow from the auroral regions into the magnetosphere. The model evaluates the outflow from 1,400 km in altitude above the 1 bar level, to 3 RS along the field line. The main ion constituents evaluated are R+ and R+3. We consider the centrifugal force exerted on the particles due to a fast rotation rate, along with the effects of field‐aligned currents present in the auroral regions. The total number flux from both auroral regions is found to be 5.5–13.0×1027 s−1, which relates to a total mass source of 5.5–17.7 kg s−1. These values are on average an order of magnitude higher than expected without the additional effects of centrifugal force and field‐aligned currents. We find the ionospheric outflow rate to be comparable to the lower estimates of the mass loading rate from Enceladus and are in agreement with recent Cassini observations. This additional mass flux into the magnetosphere can substantially affect the dynamics and composition of the inner and middle magnetosphere of Saturn.