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Denton et al. 2006
Denton, R.E., Takahashi, K., Galkin, I.A., Nsumei, P.A., Huang, X., Reinisch, B.W., Anderson, R.R., Sleeper, M.K. and Hughes, W.J. (2006). Distribution of density along magnetospheric field lines. Journal of Geophysical Research 111: doi: 10.1029/2005JA011414. issn: 0148-0227.

This paper examines the field line distribution of magnetospheric electron density and mass density. The electron density distributions from IMAGE RPI active sounding are generally monotonic. The density increases with increasing MLAT slightly faster than the dependence found from the field line dependence model of Denton et al. (2002b); in general, a power law dependence ne = ne0 (LRE/R)α with α ~ 1 appears to be appropriate within the plasmasphere, at least for geocentric radius R > 2 RE. Our comparison to RPI data included also one field line distribution at LT = 7.4, which we fit with α = 2.5, a value typical of the plasmatrough based on previous studies. We calculated the average electron density field line distribution at low MLAT using the CRRES plasma wave data and found that the density was relatively flat near the magnetic equator with no convincing evidence for an equatorial peak. Using the average values of toroidal Afven frequencies, we calculated the mass density field line distributions and found that they were roughly monotonic for LT < 6, with α = 2 appropriate for LT = 4--5 and α = 1 appropriate for LT = 5--6. At LT = 6--8, the distribution was nonmonotonic, with a local peak in mass density at the magnetic equator. Dividing the frequency data into different groups based on activity, we found that the inferred average mass density field line dependence was insensitive to geomagnetic activity at LT = 4--6 but that at LT = 6--8, the tendency for the mass density to be peaked at the magnetic equator increased with respect to larger Alfven wave amplitude and more negative Dst. The average frequency ratios at LT = 6--8 did not change if we limited the data to cases with MLT = 8--16, for which the assumed perfect conductor boundary condition was better justified. Taken together, these results imply that heavy ions are preferentially peaked at the magnetic equator for LT = 6--8, at least during more geomagnetically active periods.

BACKGROUND DATA FILES

Abstract

Keywords
Magnetospheric Physics, Plasmasphere, Magnetospheric Physics, Magnetosphere, inner, Magnetospheric Physics, Magnetospheric configuration and dynamics, Magnetospheric Physics, Numerical modeling, Magnetospheric Physics, MHD waves and instabilities (2149, 6050, 7836)
Journal
Journal of Geophysical Research
http://www.agu.org/journals/jb/
Publisher
American Geophysical Union
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