posted on 2018-08-10, 11:17authored byT. J. Bradley, S. W. H. Cowley, G. Provan, G. J. Hunt, E. J. Bunce, S. J. Wharton, I. I. Alexeev, E. S. Belenkaya, V. V. Kalegaev, M. K. Dougherty
We newly analyze Cassini magnetic field data from the 2012/2013 Saturn northern spring
interval of highly inclined orbits and compare them with similar data from late southern summer in 2008,
thus providing unique information on the seasonality of the currents that couple momentum between
Saturn’s ionosphere and magnetosphere. Inferred meridional ionospheric currents in both cases consist of a
steady component related to plasma subcorotation, together with the rotating current systems of the
northern and southern planetary period oscillations (PPOs). Subcorotation currents during the two intervals
show opposite north-south polar region asymmetries, with strong equatorward currents flowing in the
summer hemispheres but only weak currents flowing to within a few degrees of the open-closed boundary
(OCB) in the winter hemispheres, inferred due to weak polar ionospheric conductivities. Currents peak at
~1 MA rad^-1 in both hemispheres just equatorward of the open-closed boundary, associated with total
downward polar currents ~6 MA, then fall across the narrow auroral upward current region to small values at
subauroral latitudes. PPO-related currents have a similar form in both summer and winter with principal
upward and downward field-aligned currents peaking at ~1.25 MA rad^-1 being essentially collocated with
the auroral upward current and approximately equal in strength. Though northern and southern PPO
currents were approximately equal during both intervals, the currents in both hemispheres were dual
modulated by both systems during 2012/2013, with approximately half the main current closing in the
opposite ionosphere and half cross field in the magnetosphere, while only the northern hemisphere currents
were similarly dual modulated in 2008.
Funding
Work at Leicester was supported by
STFC Consolidated grant ST/N000749/1,
while work at Imperial College London
was supported by STFC Consolidated
grant ST/N000692/1. T. J. B. was supported
by STFC Quota Studentship
ST/N504117/1. Model calculations by
the Lomonosov MSU team were partially
supported by the Ministry of
Education and Science of the Russian
Federation grant 14.616.21.0084. We
thank S Kellock and the Cassini Mag
team at Imperial College for access to
processed magnetometer data and J. F.
Carbary for access to the UV auroral
boundary data shown in Figures 4d and
4e.
History
Citation
Journal of Geophysical Research: Space Physics, 2018, 123 (5), pp. 3602-3636 (35)
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Physics and Astronomy
Calibrated data from the Cassini
mission are available from the NASA
Planetary Data System at the Jet
Propulsion Laboratory (https://pds.jpl.nasa.gov/)