Contributions to the magnetospheric parallel electric field

Details Contributions to the magnetospheric parallel electric field Contributions to the magnetospheric parallel electric field

Jul 2011

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2011jgra..11607216s&link_type=abstract

Journal of Geophysical Research, Volume 116, Issue A7, CiteID A07216

Physics

Magnetospheric Physics: Electric Fields (2411), Magnetospheric Physics: Field-Aligned Currents And Current Systems (2409)

Scientific paper

Upward field-aligned currents and their associated parallel electric fields couple the ionosphere to the magnetosphere. It is desirable to know how such a potential drop is distributed along the flux tube, what controls its variation, and how it is balanced by the plasma. By considering the motion of the ionospheric and magnetospheric electrons and ions, under the influence of electrostatic and magnetic mirror forces, a quasi steady state, quasi-neutral electric field distribution along the magnetic flux tube can be obtained. A feature of the potential profiles is the occurrence of a potential jump that splits the profile into three distinct regions: below the jump, within the jump, and above the jump. Within a kinetic framework, we analyze how the plasma velocity distributions evolve along the flux tube, taking into account ionospheric, magnetospheric, mirroring, and precipitating electron populations. By calculating the moments of the governing Vlasov equation, we ascertain what balances the parallel electric field (E$\parallel$) and how it is maintained, establishing a dynamical equilibrium. Our calculations show that (1) earthward of the jump E$\parallel$ ≈ -(p$\perp$/enB)$\nabla$$\parallel$B associated with the ionospheric electrons, except for at the base of the F region where p$\parallel$ contributions become more significant; (2) within the jump magnetosphere electrons dominate and E$\parallel$ ≈ -(1/en)$\nabla$$\parallel$p$\parallel$; and (3) above the jump mirroring magnetospheric electrons make a principal contribution of E$\parallel$ ≈ -(1/en)$\nabla$$\parallel$p$\parallel$, with a secondary contribution of -(p$\perp$ - p$\parallel$)$\nabla$$\parallel$B/(ne) becoming comparable beyond ≈3 RE. Additionally, we found that although the precipitating electrons carry the field-aligned current, it is the mirroring population that determines where E$\parallel$ is concentrated and hence where precipitating electrons are accelerated.

Affiliated with

Also associated with

No associations

Rating

Contributions to the magnetospheric parallel electric field does not yet have a rating. At this time, there are no reviews or comments for this scientific paper.

If you have personal experience with Contributions to the magnetospheric parallel electric field, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Contributions to the magnetospheric parallel electric field will most certainly appreciate the feedback.

Rate now

Comments { 0 }

Profile ID: LFWR-SCP-O-996860