posted on 2015-07-23, 11:33authored byQ-H Zhang, M Lockwood, JC Foster, S-R Zhang, B-C Zhang, IW Mccrea, J Moen, M Lester, JM Ruohoniemi
Tracking the formation and full evolution of polar cap ionization patches in the polar ionosphere, we directly observe the full Dungey convection cycle for southward interplanetary magnetic field (IMF) conditions. This enables us to study how the Dungey cycle influences the patches' evolution. The patches were initially segmented from the dayside storm enhanced density plume at the equatorward edge of the cusp, by the expansion and contraction of the polar cap boundary due to pulsed dayside magnetopause reconnection, as indicated by in situ Time History of Events and Macroscale Interactions during Substorms (THEMIS) observations. Convection led to the patches entering the polar cap and being transported antisunward, while being continuously monitored by the globally distributed arrays of GPS receivers and Super Dual Auroral Radar Network radars. Changes in convection over time resulted in the patches following a range of trajectories, each of which differed somewhat from the classical twin-cell convection streamlines. Pulsed nightside reconnection, occurring as part of the magnetospheric substorm cycle, modulated the exit of the patches from the polar cap, as confirmed by coordinated observations of the magnetometer at Tromsø and European Incoherent Scatter Tromsø UHF radar. After exiting the polar cap, the patches broke up into a number of plasma blobs and returned sunward in the auroral return flow of the dawn and/or dusk convection cell. The full circulation time was about 3h.
Funding
This work is supported by the National
Basic Research Program of China (grant
2012CB825603), the National Natural
Science Foundation of China (grants
41274149, 41104091, 41031064, and
41274148), the International Collaboration
Supporting Project, Chinese Arctic and
Antarctic Administration (IC201112), and
the Shandong Provincial Natural Science
Foundation (grant JQ201412). J. Moen is
supported by the Research Council of
Norway grant 230996. M. Lester is
supported by NERC grant NE/K011766/
1. J. Foster and S.-R. Zhang receive
partial support from NSF cooperative
agreement ATM-0733510. We thank
the MIT Haystack Observatory for
generating GPS TEC data and making
them available through the Madrigal
Database (http://madrigal.haystack.
mit.edu/), and the NASA CDAWeb site
for the solar wind and IMF data from
the ACE spacecraft. J. M. Ruohoniemi is
supported by NSF grant AGS-1243070.
SuperDARN is a collection of radars
funded by national scientific funding
agencies of Australia, Canada, China,
France, Japan, South Africa, United
Kingdom, and United States of America.
History
Citation
Journal of Geophysical Research: Space Physics June 2015. 120(6), 4519–4530
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Physics and Astronomy
Version
VoR (Version of Record)
Published in
Journal of Geophysical Research: Space Physics June 2015. 120(6)