Large scale structures of the convection inferred from coordinated measurements by EISCAT and GEOS 2

D. Fontaine; S. Perraut; D. Alcaydé; G. Caudal; B. Higel

doi:10.1016/0021-9169(86)90070-X

Large scale structures of the convection inferred from coordinated measurements by EISCAT and GEOS 2

D. Fontaine
, S. Perraut
, D. Alcaydé
, G. Caudal
, B. Higel

Research output: Contribution to journal › Article › peer-review

Abstract

The equipotential lines of the ionospheric convection electric field can be derived from F-region ion drift measurements performed by EISCAT during 24 h latitudinal scans across the auroral zone. The plasmapause location can be identified with the outermost closed equipotential line from the flow pattern, taking into account the corotation electric field. This indirect prediction is compared with plasmapause crossings simultaneously observed at the geostationary orbit by the spacecraft GEOS 2 located in the vicinity of the apex of the EISCAT magnetic field line. The agreement between these two experimental results validates the method inferred from EISCAT F-region ion drift measurements. In addition, it demonstrates the capability of the EISCAT system to reproduce correctly the large scale structures of the magnetospheric convection over a wide equatorial region from about 4 to 10 Earth radii.

Original language	English
Pages (from-to)	973-986
Number of pages	14
Journal	Journal of Atmospheric and Terrestrial Physics
Volume	48
Issue number	9-10
DOIs	https://doi.org/10.1016/0021-9169(86)90070-X
Publication status	Published - 1 Jan 1986
Externally published	Yes

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title = "Large scale structures of the convection inferred from coordinated measurements by EISCAT and GEOS 2",

abstract = "The equipotential lines of the ionospheric convection electric field can be derived from F-region ion drift measurements performed by EISCAT during 24 h latitudinal scans across the auroral zone. The plasmapause location can be identified with the outermost closed equipotential line from the flow pattern, taking into account the corotation electric field. This indirect prediction is compared with plasmapause crossings simultaneously observed at the geostationary orbit by the spacecraft GEOS 2 located in the vicinity of the apex of the EISCAT magnetic field line. The agreement between these two experimental results validates the method inferred from EISCAT F-region ion drift measurements. In addition, it demonstrates the capability of the EISCAT system to reproduce correctly the large scale structures of the magnetospheric convection over a wide equatorial region from about 4 to 10 Earth radii.",

author = "D. Fontaine and S. Perraut and D. Alcayd{\'e} and G. Caudal and B. Higel",

year = "1986",

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doi = "10.1016/0021-9169(86)90070-X",

language = "English",

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TY - JOUR

T1 - Large scale structures of the convection inferred from coordinated measurements by EISCAT and GEOS 2

AU - Fontaine, D.

AU - Perraut, S.

AU - Alcaydé, D.

AU - Caudal, G.

AU - Higel, B.

PY - 1986/1/1

Y1 - 1986/1/1

N2 - The equipotential lines of the ionospheric convection electric field can be derived from F-region ion drift measurements performed by EISCAT during 24 h latitudinal scans across the auroral zone. The plasmapause location can be identified with the outermost closed equipotential line from the flow pattern, taking into account the corotation electric field. This indirect prediction is compared with plasmapause crossings simultaneously observed at the geostationary orbit by the spacecraft GEOS 2 located in the vicinity of the apex of the EISCAT magnetic field line. The agreement between these two experimental results validates the method inferred from EISCAT F-region ion drift measurements. In addition, it demonstrates the capability of the EISCAT system to reproduce correctly the large scale structures of the magnetospheric convection over a wide equatorial region from about 4 to 10 Earth radii.

AB - The equipotential lines of the ionospheric convection electric field can be derived from F-region ion drift measurements performed by EISCAT during 24 h latitudinal scans across the auroral zone. The plasmapause location can be identified with the outermost closed equipotential line from the flow pattern, taking into account the corotation electric field. This indirect prediction is compared with plasmapause crossings simultaneously observed at the geostationary orbit by the spacecraft GEOS 2 located in the vicinity of the apex of the EISCAT magnetic field line. The agreement between these two experimental results validates the method inferred from EISCAT F-region ion drift measurements. In addition, it demonstrates the capability of the EISCAT system to reproduce correctly the large scale structures of the magnetospheric convection over a wide equatorial region from about 4 to 10 Earth radii.

U2 - 10.1016/0021-9169(86)90070-X

DO - 10.1016/0021-9169(86)90070-X

M3 - Article

AN - SCOPUS:38249039493

SN - 0021-9169

VL - 48

SP - 973

EP - 986

JO - Journal of Atmospheric and Terrestrial Physics

JF - Journal of Atmospheric and Terrestrial Physics

IS - 9-10

ER -

Large scale structures of the convection inferred from coordinated measurements by EISCAT and GEOS 2

Abstract

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