Ion kinetic properties in Mercury's pre-midnight plasma sheet

Anderson; Anderson; Andrews; Baker; Baumjohann; Boardsen; Brian J. Anderson; Daniel J. Gershman; Daniel N. Baker; Delcourt; Delcourt; Delcourt; DiBraccio; Gershman; Gershman; Haje Korth; Ip; James A. Slavin; Jim M. Raines; Kistler; Korth; Korth; Lennartsson; Mouikis; Mukai; Ogilvie; Raines; Raines; Sean C. Solomon; Seki; Slavin; Solomon; Sundberg; Thomas H. Zurbuchen; Thomsen; Uritsky; Wang; Winslow; Zurbuchen

Ion kinetic properties in Mercury's pre-midnight plasma sheet

Authors: Anderson
Anderson
Andrews
Baker
Baumjohann
Boardsen
Brian J. Anderson
Daniel J. Gershman
Daniel N. Baker
Delcourt
Delcourt
Delcourt
DiBraccio
Gershman
Gershman
Haje Korth
Ip
James A. Slavin
Jim M. Raines
Kistler
Korth
Korth
Lennartsson
Mouikis
Mukai
Ogilvie
Raines
Raines
Sean C. Solomon
Seki
Slavin
Solomon
Sundberg
Thomas H. Zurbuchen
Thomsen
Uritsky
Wang
Winslow
Zurbuchen
Publication date: 1 January 2014
Publisher: 'Columbia University Libraries/Information Services'
Doi

Abstract

With data from the Fast Imaging Plasma Spectrometer sensor on the MErcury Surface, Space ENvironment, GEochemistry, and Ranging spacecraft, we demonstrate that the average distributions for both solar wind and planetary ions in Mercury’s pre-midnight plasma sheet are well-described by hot Maxwell-Boltzmann distributions. Temperatures and densities of the H+ ranges ~1–10 cm3 and ~5–30 MK, respectively, maintain thermal pressures of ~1 nPa. The dominant planetary ion, Na+ abundances with respect to H+ and exhibit mass-proportional ion temperatures, indicative of a reconnection-dominated heating in the magnetosphere. Conversely, planetary ion species are accelerated to similar average energies greater by a factor of ~1.5 than that of H+ acceleration in an electric potential, consistent with the presence of a strong centrifugal acceleration process in Mercury’s magnetosphere