Magnetopause location under extreme solar wind conditions

Shue, J.‐H.; Song, P.; Russell, C. T.; Steinberg, J. T.; Chao, J. K.; Zastenker, G. N.; Вайсберг, О. Л.; Kokubun, S.; Singer, H. J.; Detman, T.; Kawano, Hideaki

doi:10.1029/98ja01103

Cited by 916 publications

(1,672 citation statements)

References 17 publications

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“…[12] A large negative B z , as well as increasing of the dynamic pressure, is a controlling parameter for the reduction of the dayside magnetopause dimension [Roelof and Sibeck, 1993;Petrinec and Russell, 1996;Shue et al, 1998, and references therein]. The above connection of the LENA emission to both the solar wind dynamic pressure and IMF B z indicates that the reduction of the dayside magnetopause dimension is a major controlling parameter for the LENA emission enhancements.…”

Section: Variations Of Lena Hydrogen Counts and Goes 8 Magnetic Fieldmentioning

confidence: 99%

“…While these types of models have successfully predicted the motion of the magnetopause near the equatorial plane even for extreme solar wind situations [Shue et al, 1998], it is still unclear to what extent the validity of the models, which assume cylindrical symmetry around the aberrated Sun-Earth direction, can be extended to the X-Z meridian structure. In this meridian the magnetopause has a cusp indentation, and the characteristics of this indentation, in particular, the solar wind control of the location, need to be clarified for a full understanding of the dynamic features of the magnetopause.…”

Section: Introductionmentioning

confidence: 99%

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Response of neutral atom emissions in the low‐latitude and high‐latitude magnetosheath direction to the magnetopause motion under extreme solar wind conditions

et al. 2004

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On 11 April 2001 the high velocity and density of the solar wind and the strong southward interplanetary magnetic field moved the dayside magnetopause inside of geosynchronous orbit. The Low Energy Neutral Atom (LENA) imager on the Imager for Magnetopause‐to‐Aurora Global Exploration (IMAGE) spacecraft in the magnetosphere observed significant emission in the magnetosheath direction. The total neutral atom flux from the dayside region, ignoring the neutral solar wind flux directly from the Sun, shows a threefold enhancement, and each of the three increases is coincident with the occurrence of the magnetopause inside 6.6 RE. Observations by LENA also show that emission in the direction of the low‐latitude and high‐latitude magnetosheath is modulated in such a manner that the sources shift earthward/sunward and equatorward/poleward in the low‐latitude and high‐latitude sheath, respectively. A model based on the distributions of the sheath flux and of the number density of the hydrogen exosphere explains these characteristics as a result of the motion of the magnetopause having an indentation at the cusp, suggesting a means for monitoring the cusp motion using IMAGE/LENA.

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Section: Variations Of Lena Hydrogen Counts and Goes 8 Magnetic Fieldmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Response of neutral atom emissions in the low‐latitude and high‐latitude magnetosheath direction to the magnetopause motion under extreme solar wind conditions

et al. 2004

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“…The statistical data ordering is essentially based on the magnetosheath-interplanetary medium (MIPM) reference frame developed by Verigin et al [2006]. This consists of a spatial superposed analysis which orders spacecraft data from a given time and location relative to models of the magnetopause [Shue et al, 1997[Shue et al, , 1998] and bow shock positions [Verigin et al, 2006]. Using appropriately lagged (using Cluster and ACE spacecraft positions and the measured solar wind velocity at ACE) ACE data as inputs to the models, a fractional position of Cluster in the magnetosheath, relative to the model boundaries (between 0 and 1), is obtained along the direction of the spacecraft position vector (see also Nĕmecek et al [2000Nĕmecek et al [ , 2003 for similar procedures).…”

Section: Statistical Study Of Magnetosheath Flowsmentioning

confidence: 99%

“…Statistical distribution of the magnetosheath ion speed measured at Cluster normalized to the appropriately lagged ion speed measured at ACE for each 5 min data averages; a color palette of |V SHEATH |/|V SW | is given in the top right corner. The statistical data ordering is based on the magnetosheath-interplanetary medium (MIPM) reference frame developed by Verigin et al [2006], using models of the magnetopause [Shue et al, 1997[Shue et al, , 1998] and bow shock positions [Verigin et al, 2006] with appropriately lagged ACE data as inputs. Each data point is assigned an X and R (R = √(Y 2 + Z 2 )) position in the normalized reference frame.…”

Section: Statistical Study Of the Magnetopause Shapementioning

confidence: 99%

“…[23] In order to highlight a relative change in magnetopause shape, the observed magnetopause distances from our crossings lists are then compared to the Shue et al [1997Shue et al [ , 1998] model for the prevailing solar wind conditions (with IMF B Z and dynamic pressure as input). We here use the difference (R REAL À R SHUE ) between the observed and Figure 5.…”

Section: Statistical Study Of the Magnetopause Shapementioning

confidence: 99%

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Asymmetry of magnetosheath flows and magnetopause shape during low Alfvén Mach number solar wind

et al. 2013

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[1] Previous works have emphasized the significant influence of the solar wind Alfvén Mach number (M A ) on magnetospheric dynamics. Here we report statistical, observational results that pertain to changes in the magnetosheath flow distribution and magnetopause shape as a function of solar wind M A and interplanetary magnetic field (IMF) clock angle orientation. We use all Cluster 1 data in the magnetosheath during the period 2001-2010, using an appropriate spatial superposition procedure, to produce magnetosheath flow distributions as a function of location in the magnetosheath relative to the IMF and other parameters. The results demonstrate that enhanced flows in the magnetosheath are expected at locations quasi-perpendicular to the IMF direction in the plane perpendicular to the Sun-Earth line; in other words, for the special case of a northward IMF, enhanced flows are observed on the dawn and dusk flanks of the magnetosphere, while much lower flows are observed above the poles. The largest flows are adjacent to the magnetopause. Using appropriate magnetopause crossing lists (for both high and low M A ), we also investigate the changes in magnetopause shape as a function of solar wind M A and IMF orientation. Comparing observed magnetopause crossings with predicted positions from an axisymmetric semi-empirical model, we statistically show that the magnetopause is generally circular during high M A , while is it elongated (albeit with moderate statistical significance) along the direction of the IMF during low M A . These findings are consistent with enhanced magnetic forces that prevail in the magnetosheath during low M A . The component of the magnetic forces parallel to the magnetopause produces the enhanced flows along and adjacent to the magnetopause, while the component normal to the magnetopause exerts an asymmetric pressure on the magnetopause that deforms it into an elongated shape.

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Alternative interpretation of results from Kelvin‐Helmholtz vortex identification criteria

Plaschke

Taylor

Nakamura

2014

Geophysical Research Letters

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Observations of lower density, faster than sheath (LDFTS) plasma at the magnetopause are believed to be specific to rolled‐up vortices generated by the Kelvin‐Helmholtz instability. Hence, they are used to identify vortices with single‐spacecraft measurements. These vortices are expected to occur at the tail‐flank magnetopause, beyond the terminator. This fact contrasts with numerous observations of LDFTS plasma far sunward of the terminator. Here we present two alternative explanations for the detection of LDFTS plasma at the dayside magnetopause: (1) the presence of a plasma depletion layer (PDL) readily featuring LDFTS plasma and (2) the plasma velocity pattern of magnetopause surface waves, by which lower/higher‐density magnetosheath or PDL plasmas sensed by a wave‐observing spacecraft are accelerated/decelerated in magnetosheath flow direction. Even low‐latitude boundary layer (LLBL) plasma may be of LDFTS, if the LLBL background flow is antisunward at near‐magnetosheath velocities.

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Magnetopause location under extreme solar wind conditions

Cited by 916 publications

References 17 publications

Response of neutral atom emissions in the low‐latitude and high‐latitude magnetosheath direction to the magnetopause motion under extreme solar wind conditions

Response of neutral atom emissions in the low‐latitude and high‐latitude magnetosheath direction to the magnetopause motion under extreme solar wind conditions

Asymmetry of magnetosheath flows and magnetopause shape during low Alfvén Mach number solar wind

Alternative interpretation of results from Kelvin‐Helmholtz vortex identification criteria

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