Journal ArticleDOI
Solar wind control of the polar cusp at high altitude
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In this paper, the authors study the statistical behavior of the high-altitude polar cusp location and its dependence on the solar wind conditions and find that the invariant latitude of the center of the cusp varies from 70° to 86° as solar wind condition changes and the magnetic local time of the footprints of the Cusp magnetic field lines extends from 0800 to 1600 MLT.Abstract:
The POLAR mission is ideally suited to study the high-altitude polar cusp. Polar magnetometer data, together with electron and ion measurements from the Hydra and Toroidal Imaging Mass-Angle Spectrograph (Timas) instruments from March 1996 to December 1997, have been used to identify 459 polar cusp crossings. These crossings are used to study the statistical behavior of the cusp location and its dependence on the solar wind conditions. We find that the invariant latitude of the center of the cusp varies from 70° to 86° as solar wind conditions change and the magnetic local time of the footprints of the cusp magnetic field lines extends from 0800 to 1600 MLT, the cusp being slightly wider for increasing solar wind dynamic pressure. The average latitude of the center of the cusp is at 80.3° invariant latitude at noon and decreases to 78.7° at 0800 and 1600 MLT. The cusp also appears to thicken slightly in invariant latitude with increasing dynamic pressure. The center of the cusp moves equatorward with increasingly southward interplanetary magnetic field (IMF) to 73° invariant latitude for a 10 nT southward IMF. The cusp moves only slightly for northward IMF. This motion is consistent with erosion of dayside magnetic flux for southward IMF but little or no erosion for northward IMF. The cusp is also somewhat wider in invariant latitude with increasingly northward IMF. Consistent with low-altitude observations, we find that there is a clear MLT shift due to the IMF By for strongly southward IMF. We interpret the motion of the local time of the cusp for southward IMF as a shift of the reconnection site away from the noon meridian when the IMF is not due southward.read more
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Journal ArticleDOI
A three-dimensional asymmetric magnetopause model
TL;DR: In this article, a new three-dimensional asymmetric magnetopause model has been developed for corrected GSM coordinates and parameterized by the solar wind dynamic and magnetic pressures (Pd + Pm), the interplanetary magnetic field (IMF) Bz, and the dipole tilt angle.
Journal ArticleDOI
MESSENGER observations of Mercury's dayside magnetosphere under extreme solar wind conditions
James A. Slavin,Gina A. DiBraccio,Daniel J. Gershman,Daniel J. Gershman,Suzanne M. Imber,Suzanne M. Imber,Gangkai Poh,Jim M. Raines,Thomas H. Zurbuchen,Xianzhe Jia,Daniel N. Baker,Karl-Heinz Glassmeier,Stefano Livi,Scott A. Boardsen,Scott A. Boardsen,Timothy A. Cassidy,Menelaos Sarantos,Menelaos Sarantos,Torbjörn Sundberg,Adam Masters,Catherine L. Johnson,Catherine L. Johnson,Reka M. Winslow,Reka M. Winslow,Brian J. Anderson,Haje Korth,Ralph L. McNutt,Sean C. Solomon,Sean C. Solomon +28 more
TL;DR: The MESSENGER project is supported by the NASA Discovery Programme under contracts NASW-============00002 to the Carnegie Institution of======Washington and NAS5-97271 to The Johns Hopkins University Applied======Physics Laboratory.
Journal ArticleDOI
Observations of Mercury's northern cusp region with MESSENGER's Magnetometer
Reka M. Winslow,Catherine L. Johnson,Catherine L. Johnson,Brian J. Anderson,Haje Korth,James A. Slavin,Michael E. Purucker,Sean C. Solomon +7 more
TL;DR: The magnetic cusp of a planetary magnetosphere allows solar wind plasma to gain access to the planet's magnetosphere and, for Mercury, the surface as mentioned in this paper, the magnetic field in the northern cusp region of Mercury is characterized by the MESSENGER magnetometer.
Journal ArticleDOI
Double cusp: Model prediction and observational verification
TL;DR: An improved model that incorporates the electric field obtained from statistical convection patterns is presented that is consistent with the following new statistical results: (1) the cusp latitudinal width increases with |IMF By| and (2) thecusp equatorward boundary moves to lower latitude with increasing |IMf By|.
References
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Journal ArticleDOI
Dayside merging and cusp geometry
TL;DR: In this paper, it was shown that dayside magnetic merging when constrained to act only where the fields are antiparallel results in lines of merging that converge at the polar cusps.
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Modeling the global magnetic field of the large‐scale Birkeland current systems
TL;DR: In this article, a tilt-dependent model of the Birkeland current sheets, based on the formalism of Euler potentials, was developed for representing the global distribution of the average magnetic field produced by the region 1 and 2 BIC systems.
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The cusp and the cleft/boundary layer: Low-altitude identification and statistical local time variation
Patrick T. Newell,Ching-I. Meng +1 more
TL;DR: In this paper, the authors investigated the distinction between the low-altitude cusp and the cleft (with the latter identified as the ionospheric signature of low-latitude boundary layer (LLBL)) on both a statistical and a case study basis.
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Some low-altitude cusp dependencies on the interplanetary magnetic field
TL;DR: In this article, the low-altitude cusp dependencies on the interplanetary magnetic field (IMF) were investigated using the algorithm of Newell and Meng (1988) to identify the cusp proper.
Journal ArticleDOI
Inward motion of the magnetopause before a substorm
TL;DR: Magnetopause inward motion before substorm, showing association with interplanetary field vertical component reversal as mentioned in this paper, was found to be associated with inter-planetary magnetic fields.