Dawn/dusk asymmetry in particles of solar wind origin within the magnetosphere
Dawn/dusk asymmetry in particles of solar wind origin within the magnetosphere
Solar wind/magnetosheath plasma in the magnetosphere can be identified using a component that has a higher charge state, lower density and, at least soon after their entry into the magnetosphere, lower energy than plasma from a terrestrial source. We survey here observations taken over 3 years of He2+ ions made by the Magnetospheric Ion Composition Sensor (MICS) of the Charge and Mass Magnetospheric Ion Composition Experiment (CAMMICE) instrument aboard POLAR. The occurrence probability of these solar wind ions is then plotted as a function of Magnetic Local Time (MLT) and invariant latitude (7) for various energy ranges. For all energies observed by MICS (1.8–21.4 keV) and all solar wind conditions, the occurrence probabilities peaked around the cusp region and along the dawn flank. The solar wind conditions were filtered to see if this dawnward asymmetry is controlled by the Svalgaard-Mansurov effect (and so depends on the BY component of the interplanetary magnetic field, IMF) or by Fermi acceleration of He2+ at the bow shock (and so depends on the IMF ratio BX /BY ). It is shown that the asymmetry remained persistently on the dawn flank, suggesting it was not due to effects associated with direct entry into the magnetosphere. This asymmetry, with enhanced fluxes on the dawn flank, persisted for lower energy ions (below a "cross-over" energy of about 23 keV) but reversed sense to give higher fluxes on the dusk flank at higher energies. This can be explained by the competing effects of gradient/curvature drifts and the convection electric field on ions that are convecting sunward on re-closed field lines. The lower-energy He2+ ions E × B drift dawnwards as they move earthward, whereas the higher energy ions curvature/ gradient drift towards dusk. The convection electric field in the tail is weaker for northward IMF. Ions then need less energy to drift to the dusk flank, so that the cross-over energy, at which the asymmetry changes sense, is reduced.
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Stubbs, T.J.
eac172fc-50fb-4bad-8a38-e19bb36559e5
Lockwood, M.
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Cargill, P.
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Fennel, J.
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Grande, M.
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Kellett, B.
457a0486-c48f-480e-864d-27e1f3e300bd
Perry, C.H.
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Rees, A.
d598ede0-e474-4fef-bf44-55a8975ad729
2001
Stubbs, T.J.
eac172fc-50fb-4bad-8a38-e19bb36559e5
Lockwood, M.
32917473-f7d9-4773-9162-6509baad09fa
Cargill, P.
b4183b41-abf2-4af1-9fe5-e98905132382
Fennel, J.
e86213ac-5b46-47c8-9333-daeec915835d
Grande, M.
4efb9321-a323-45b0-8fd2-e26c01b47b5e
Kellett, B.
457a0486-c48f-480e-864d-27e1f3e300bd
Perry, C.H.
b39ea249-54c0-444d-8834-5de309366cdf
Rees, A.
d598ede0-e474-4fef-bf44-55a8975ad729
Stubbs, T.J., Lockwood, M., Cargill, P., Fennel, J., Grande, M., Kellett, B., Perry, C.H. and Rees, A.
(2001)
Dawn/dusk asymmetry in particles of solar wind origin within the magnetosphere.
Annales Geophysicae, 19, .
Abstract
Solar wind/magnetosheath plasma in the magnetosphere can be identified using a component that has a higher charge state, lower density and, at least soon after their entry into the magnetosphere, lower energy than plasma from a terrestrial source. We survey here observations taken over 3 years of He2+ ions made by the Magnetospheric Ion Composition Sensor (MICS) of the Charge and Mass Magnetospheric Ion Composition Experiment (CAMMICE) instrument aboard POLAR. The occurrence probability of these solar wind ions is then plotted as a function of Magnetic Local Time (MLT) and invariant latitude (7) for various energy ranges. For all energies observed by MICS (1.8–21.4 keV) and all solar wind conditions, the occurrence probabilities peaked around the cusp region and along the dawn flank. The solar wind conditions were filtered to see if this dawnward asymmetry is controlled by the Svalgaard-Mansurov effect (and so depends on the BY component of the interplanetary magnetic field, IMF) or by Fermi acceleration of He2+ at the bow shock (and so depends on the IMF ratio BX /BY ). It is shown that the asymmetry remained persistently on the dawn flank, suggesting it was not due to effects associated with direct entry into the magnetosphere. This asymmetry, with enhanced fluxes on the dawn flank, persisted for lower energy ions (below a "cross-over" energy of about 23 keV) but reversed sense to give higher fluxes on the dusk flank at higher energies. This can be explained by the competing effects of gradient/curvature drifts and the convection electric field on ions that are convecting sunward on re-closed field lines. The lower-energy He2+ ions E × B drift dawnwards as they move earthward, whereas the higher energy ions curvature/ gradient drift towards dusk. The convection electric field in the tail is weaker for northward IMF. Ions then need less energy to drift to the dusk flank, so that the cross-over energy, at which the asymmetry changes sense, is reduced.
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Published date: 2001
Identifiers
Local EPrints ID: 9166
URI: http://eprints.soton.ac.uk/id/eprint/9166
ISSN: 0992-7689
PURE UUID: f464dff6-32f2-4ae1-81f5-b72a65b87200
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Date deposited: 24 Sep 2004
Last modified: 08 Jan 2022 03:42
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Contributors
Author:
T.J. Stubbs
Author:
M. Lockwood
Author:
P. Cargill
Author:
J. Fennel
Author:
M. Grande
Author:
B. Kellett
Author:
C.H. Perry
Author:
A. Rees
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