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Acceleration of Solar Wind Particles Passing through the 3D Heliospheric Current Sheet

Published online by Cambridge University Press:  24 July 2018

Valentina V. Zharkova
Valentina V. Zharkova*
Affiliation:
Department of Mathematics, Physics and Electrical Engineering, University of Northumbria, Newcastle upon Tyne, NE1 8ST, UK email: valentina.zharkova@northumbria.ac.uk
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Abstract

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Additional acceleration of protons and electrons passing through a 3D reconnecting current sheet (RCS) of the solar corona and heliosphere is investigated with PIC approach. The simulation confirms spatial separation of electrons and protons and generation of a polarisation electric field induced by separated particles. In the heliospheric current sheet with a weak magnetic field there are two populations of particles: transit and bounced. The transit particles (both protons and electrons) are accelerated to high energies while the bounced electrons fail to reach the midplane. Instead they form an electron cloud of horseshoe or medallion types at some distance D from its midplane, which is larger for bigger guiding field magnitudes. These energetic electrons and protons appearing near the HCS boundaries can be a great danger for the satellites crossing the sector boundaries.

Keywords

Sun: flaresplasmasacceleration of particlesmagnetic field
Type
Contributed Papers
Information
Proceedings of the International Astronomical Union , Volume 13 , Symposium S335: Space Weather of the Heliosphere: Processes and Forecasts , July 2017 , pp. 54 - 57
Copyright
Copyright © International Astronomical Union 2018 

References

Crooker, N. U., Forsyth, R., Rees, A., Gosling, J. T. & Kahler, S. W. 2004a, Journal of Geophysical Research (Space Physics), 109, A06110Google Scholar
Crooker, N. U., Huang, C.-L., Lamassa, S. M., et al. 2004b, Journal of Geophysical Research (Space Physics), 109, A03107Google Scholar
Gosling, J. T., Eriksson, S. & Schwenn, R. 2006a, Journal of Geophysical Research (Space Physics), 111, A10102Google Scholar
Gosling, J. T., McComas, D. J., Skoug, R. M. & Smith, C. W. 2006b, Geophysics Research Letters, 33, L17102CrossRefGoogle Scholar
Kahler, S. & Lin, R. P. 1994, Geophysics Research Letters, 21, 1575CrossRefGoogle Scholar
Kahler, S. W. & Lin, R. P. 1995, Solar Physics, 161, 183Google Scholar
Lin, R. P., Ko, Y. K., Sui, L., et al. 2005, Astrophysical Journal, 622, 1251Google Scholar
Priest, E. & Forbes, T. 2000, Magnetic Reconnection (Magnetic Reconnection, by Priest, Eric and Forbes, Terry, pp. 612. ISBN 0521481791. Cambridge, UK: Cambridge University Press, June 2000.)Google Scholar
Siversky, T. V. & Zharkova, V. V. 2009, Journal of Plasma Physics, 75, 619CrossRefGoogle Scholar
Verboncoeur, J. P. Langdon, A. B. & Gladd, N. T. 1995, Comp. Phys. Comm., 87, 199Google Scholar
Wood, P. & Neukirch, T. 2005, Solar Physics, 226, 73CrossRefGoogle Scholar
Zharkova, V. V. & Gordovskyy, M. 2004, Astrophysical Journal, 604, 884Google Scholar
Zharkova, V. V. & Gordovskyy, M. 2005, Monthly Notices of the Royal Astronomical Society, 356, 11071116.Google Scholar
Zharkova, V. V. & Agapitov, O. V. 2009, Journal of Plasma Physics, 75, 159CrossRefGoogle Scholar
Zharkova, V. V. & Khabarova, O. V. 2012, Astrophysical Journal, Vol. 752, 35Google Scholar
Zharkova, V. V. & Khabarova, O. V. 2015, Annales Geophys., 33, 457CrossRefGoogle Scholar