University of Leicester
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North-South Asymmetries in Earth's Magnetic Field

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journal contribution
posted on 2018-05-11, 12:44 authored by K. M. Laundal, I. Cnossen, Stephen E. Milan, S. E. Haaland, J. Coxon, N. M. Pedatella, M. Foerster, J. P. Reistad
The solar-wind magnetosphere interaction primarily occurs at altitudes where the dipole component of Earth’s magnetic field is dominating. The disturbances that are created in this interaction propagate along magnetic field lines and interact with the ionosphere–thermosphere system. At ionospheric altitudes, the Earth’s field deviates significantly from a dipole. North–South asymmetries in the magnetic field imply that the magnetosphere–ionosphere–thermosphere (M–I–T) coupling is different in the two hemispheres. In this paper we review the primary differences in the magnetic field at polar latitudes, and the consequences that these have for the M–I–T coupling. We focus on two interhemispheric differences which are thought to have the strongest effects: 1) A difference in the offset between magnetic and geographic poles in the Northern and Southern Hemispheres, and 2) differences in the magnetic field strength at magnetically conjugate regions. These asymmetries lead to differences in plasma convection, neutral winds, total electron content, ion outflow, ionospheric currents and auroral precipitation.

History

Citation

Space Science Reviews, 2017, 206 (1-4), pp. 225-257

Author affiliation

/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Physics and Astronomy

Version

  • VoR (Version of Record)

Published in

Space Science Reviews

Publisher

Springer Verlag

issn

0038-6308

eissn

1572-9672

Acceptance date

2016-06-25

Copyright date

2016

Available date

2018-05-11

Publisher version

https://link.springer.com/article/10.1007/s11214-016-0273-0

Language

en