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Krauss-Varban & Burgess 1991
Krauss-Varban, D. and Burgess, D. (1991). Electron acceleration at nearly perpendicular collisionless shocks: 2. Reflection at curved shocks. Journal of Geophysical Research 96: doi: 10.1029/90JA01728. issn: 0148-0227.

Electrons can be efficiently energized at interplanetary shocks and planetary bow shocks. The acceleration and reflection process is extremely sensitive to the angle &thgr;Bn between the upstream magnetic field and the shock normal, and is most prominent at &thgr;Bn~90¿. The mechanism has been investigated by theoretical and simulation means, and can be interpreted as a fast Fermi process or as gradient drift acceleration. Previous work has been carried out for plane shocks only, and is expanded here to take into account the global curvature of a shock. Simple estimates suggest that this curvature may have a strong limiting effect on the acceleration to high energies, i.e., above several keV in case of the Earth's bow shock. We perform two-dimensional test particle calculations to address this question, and evaluate the reflected electron flux as a function of &thgr;Bn at the shock surface. The shock profile is derived from hybrid code simulations, and modified to include the first order effects of a global curvature in the vicinity of &thgr;Bn=90¿.

At low energies, the calculated fluxes exhibit a cut-off and a maximum, which can give rise to observed bump-on-tail distributions in the electron foreshock. Results at high energy show that while individual electrons gain less energy in a curved shock, concerning the flux this fact is largely offset by two-dimensional focusing effects. Electrons that drift into the shock over a wide area converge and stream out within a narrow spatial area, thus greatly enhancing the flux of reflected electrons. A &kgr; distribution of suprathermal solar wind electrons (of index &kgr;=6) is capable of producing the observed large fluxes of reflected electrons at the Earth's bow shock up to energies of 10 to 15 keV, even when the global shock curvature is accounted for. Beyond this energy range observed spectra are harder, as has been found previously for a plane shock. As a likely reason, the solar wind speed population may be denser than modeled above several keV. ¿ American Geophysical Union 1991

BACKGROUND DATA FILES

Abstract

Keywords
Interplanetary Physics, Energetic particles, Space Plasma Physics, Charged particle motion and acceleration, Space Plasma Physics, Numerical simulation studies, Space Plasma Physics, Shock waves
Journal
Journal of Geophysical Research
http://www.agu.org/journals/jb/
Publisher
American Geophysical Union
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