%0 Journal Article
%@ 0094-8276
%A Hill, TW
%A Rymer, AM
%A Burch, JL
%A Crary, FJ
%A Young, DT
%A Thomsen, MF
%A Delapp, D
%A Andre, N
%A Coates, AJ
%A Lewis, GR
%D 2005
%F discovery:120191
%I AMER GEOPHYSICAL UNION
%J Geophysical Research Letters
%K Io torus, Jovian magnetosphere, Jupiters inner, Interchange, Corotation, Signatures
%N 14
%T Evidence for rotationally driven plasma transport in Saturn's magnetosphere
%U https://discovery.ucl.ac.uk/id/eprint/120191/
%V 32
%X [ 1] Radial convective transport of plasma in a rotation-dominated magnetosphere implies alternating longitudinal sectors of cooler, denser plasma moving outward and hotter, more tenuous plasma moving inward. The Cassini Plasma Spectrometer ( CAPS) has provided dramatic new evidence of this process operating in the magnetosphere of Saturn. The inward transport of hot plasma is accompanied by adiabatic gradient and curvature drift, producing a V-shaped dispersion signature on a linear energy-time plot. Of the many (similar to 100) such signatures evident during the first two Cassini orbits, we analyze a subset ( 48) that are sufficiently isolated to allow determination of their ages, widths, and injection locations. Ages are typically < 10.8 hr ( Saturn's rotation period) but range up to several rotation periods. Widths are typically < 1 RS ( Saturn's radius) but range up to several RS. Injection locations are randomly distributed in local time and in Saturnian longitude. The apex of the V sometimes coincides with a localized density cavity in the cooler background plasma, and usually coincides with a localized diamagnetic depression of the magnetic field strength. These signatures are fully consistent with the convective motions that are expected to result from the centrifugal interchange instability.
%Z Copyright 2005 by the American Geophysical Union