posted on 2019-06-21, 09:22authored byIA Pensionerov, II Alexeev, ES Belenkaya, JEP Connerney, SWH Cowley
We develop a new empirical model of Jupiter's equatorial current sheet or magnetodisk, constructed by combining successful elements from several previous models. The new model employs a disk-like current of constant north-south thickness in which the current density is piecewise dependent on the distance ρ from Jupiter's dipole axis, proportional to ρ −1 at distances between ∼7 and ∼30 R J and again at distances between ∼50 and ∼95 R J , and to be continuous in value but proportional to ρ −2 at distances between. For this reason we term the model the Piecewise Current Disk model. The model also takes into account the curvature of the magnetodisk with distance and azimuth due to finite radial propagation speed and solar wind effects. It is taken to be applicable in the radial distance range between ∼5 and ∼60 R J . Optimized parameters have been determined for Juno magnetic field data obtained on Perijove-01, with the model showing overall the lowest root-mean-square deviation from the data compared with similarly optimized earlier models.
Funding
Work at the Federal State Budget
Educational Institution of Higher
Education M.V. Lomonosov Moscow
State University, Skobeltsyn Institute
of Nuclear Physics (SINP MSU), was
partially supported by the Ministry
of Education and Science of
the Russian Federation (grant
RFMEFI61617X0084). Work at the
University of Leicester was supported
by STFC Consolidated Grant
ST/N000749/1. The Juno
magnetometer data were obtained
from the Planetary Data System (PDS;
https://pds-ppi.igpp.ucla.edu). We are
grateful to the Juno team for making
the magnetic field data available (FGM
instrument scientist J. E. P. Connerney;
principal investigator of Juno mission
Scott J. Bolton).
History
Citation
Journal of Geophysical Research: Space Physics, 2019, 124(3), pp. 1843-1854
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Physics and Astronomy