On the entry and transit of high-density plasma across the polar cap

[1] Observations are presented from SuperDARN and the EISCAT Svalbard Radar of two intense polar cap patch events on 6 February 2001. The interplanetary magnetic field (IMF) was dominated by a large positive By component, and for both events the electron density exceeded 1012 m−3 in the F region. Wi...

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Bibliographic Details
Main Authors: K. Oksavik, V. L. Barth, J. Moen, M. Lester
Format: Other Non-Article Part of Journal/Newspaper
Language:unknown
Published: 2010
Subjects:
Uncategorized
IR content
Svalbard
EISCAT
Alaska
Online Access:https://figshare.com/articles/journal_contribution/On_the_entry_and_transit_of_high-density_plasma_across_the_polar_cap/10115819
id ftleicesterunfig:oai:figshare.com:article/10115819
record_format openpolar
spelling ftleicesterunfig:oai:figshare.com:article/10115819 2023-05-15T16:04:47+02:00 On the entry and transit of high-density plasma across the polar cap K. Oksavik V. L. Barth J. Moen M. Lester 2010-12-07T00:00:00Z https://figshare.com/articles/journal_contribution/On_the_entry_and_transit_of_high-density_plasma_across_the_polar_cap/10115819 unknown 2381/20453 https://figshare.com/articles/journal_contribution/On_the_entry_and_transit_of_high-density_plasma_across_the_polar_cap/10115819 All Rights Reserved Uncategorized IR content Text Journal contribution 2010 ftleicesterunfig 2021-11-11T20:04:48Z [1] Observations are presented from SuperDARN and the EISCAT Svalbard Radar of two intense polar cap patch events on 6 February 2001. The interplanetary magnetic field (IMF) was dominated by a large positive By component, and for both events the electron density exceeded 1012 m−3 in the F region. With SuperDARN we tracked the events all the way across the polar cap, from the dayside Svalbard sector to the nightside Alaska sector. The flow speed was highly dynamic and pulsed, and both patches underwent substantial rotation in the polar cap. On the nightside the leading edge had become the trailing edge. It suggests that the first patch to enter the polar cap on the dayside may not always be the first patch to reach the nightside; plasma might be stagnant in the polar cap or even overtaken. The study also provides evidence that momentum transfer in the dayside polar cap can last significantly longer than 10 min after reconnection, especially for extremely long field lines where IMF By is dominating, i.e., on “old open field lines.” Knowledge of the solar wind driver and the coupling processes is therefore extremely important for predicting the motion of a polar cap patch event across the polar cap. Gradients in the plasma flow associated with the rotation of the extreme density may in itself lead to a stronger growth of ionospheric irregularities. These irregularities may continue to grow all the way across the polar cap. The result is more efficient creation of ionospheric irregularities. Other Non-Article Part of Journal/Newspaper EISCAT Svalbard Alaska University of Leicester: Figshare Svalbard
institution Open Polar
collection University of Leicester: Figshare
op_collection_id ftleicesterunfig
language unknown
topic Uncategorized
IR content
spellingShingle Uncategorized
IR content
K. Oksavik
V. L. Barth
J. Moen
M. Lester
On the entry and transit of high-density plasma across the polar cap
topic_facet Uncategorized
IR content
description [1] Observations are presented from SuperDARN and the EISCAT Svalbard Radar of two intense polar cap patch events on 6 February 2001. The interplanetary magnetic field (IMF) was dominated by a large positive By component, and for both events the electron density exceeded 1012 m−3 in the F region. With SuperDARN we tracked the events all the way across the polar cap, from the dayside Svalbard sector to the nightside Alaska sector. The flow speed was highly dynamic and pulsed, and both patches underwent substantial rotation in the polar cap. On the nightside the leading edge had become the trailing edge. It suggests that the first patch to enter the polar cap on the dayside may not always be the first patch to reach the nightside; plasma might be stagnant in the polar cap or even overtaken. The study also provides evidence that momentum transfer in the dayside polar cap can last significantly longer than 10 min after reconnection, especially for extremely long field lines where IMF By is dominating, i.e., on “old open field lines.” Knowledge of the solar wind driver and the coupling processes is therefore extremely important for predicting the motion of a polar cap patch event across the polar cap. Gradients in the plasma flow associated with the rotation of the extreme density may in itself lead to a stronger growth of ionospheric irregularities. These irregularities may continue to grow all the way across the polar cap. The result is more efficient creation of ionospheric irregularities.
format Other Non-Article Part of Journal/Newspaper
author K. Oksavik
V. L. Barth
J. Moen
M. Lester
author_facet K. Oksavik
V. L. Barth
J. Moen
M. Lester
author_sort K. Oksavik
title On the entry and transit of high-density plasma across the polar cap
title_short On the entry and transit of high-density plasma across the polar cap
title_full On the entry and transit of high-density plasma across the polar cap
title_fullStr On the entry and transit of high-density plasma across the polar cap
title_full_unstemmed On the entry and transit of high-density plasma across the polar cap
title_sort on the entry and transit of high-density plasma across the polar cap
publishDate 2010
url https://figshare.com/articles/journal_contribution/On_the_entry_and_transit_of_high-density_plasma_across_the_polar_cap/10115819
geographic Svalbard
geographic_facet Svalbard
genre EISCAT
Svalbard
Alaska
genre_facet EISCAT
Svalbard
Alaska
op_relation 2381/20453
https://figshare.com/articles/journal_contribution/On_the_entry_and_transit_of_high-density_plasma_across_the_polar_cap/10115819
op_rights All Rights Reserved
_version_ 1766400416779599872

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