Flux ropes in the Hermean magnetotail: Distribution, properties, and formation

Smith, A. W.; Slavin, J. A.; Jackman, C. M.; Poh, Gangkai; Fear, R. C.

doi:10.1002/2017ja024295

Cited by 26 publications

(99 citation statements)

References 78 publications

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“…The distribution of flux ropes is skewed toward dawnside on Mercury's magnetotail as shown in Figure . This feature is similar to the previous observations (Poh et al, ; Smith et al, ; Sun et al, ) and is different from the distributions in Earth's magnetotail (e.g., Imber et al, ; Slavin et al, ). In the Earth's studies, flux ropes and TCRs were more frequently observed on the duskside than on the dawnside in the near Earth neutral line region (Imber et al, ; Slavin et al, , ).…”

Section: Discussionsupporting

confidence: 90%

A Statistical Study of the Force Balance and Structure in the Flux Ropes in Mercury's Magnetotail

et al. 2019

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This study presents a statistical investigation of the force balance and structures in the flux ropes in Mercury's magnetotail plasma sheet by using the measurements of MErcury Surface, Space ENviroment, GEochemistry, and Ranging (MESSENGER). One hundred sixty‐eight flux ropes were identified from the 14 hot seasons of MESSENGER from 11 March 2011 to 30 April 2015, and 143 of them show clear magnetic field enhancements with the core field being ≥20% higher than the background magnetic field. The investigation on the force balance of these 143 flux ropes shows that magnetic pressure gradient force cannot be solely balanced by magnetic tension force, implying that thermal plasma pressure gradient force cannot be neglected in the flux ropes. We employ a non‐force‐free model considering the contribution of thermal pressure to resolve the physical properties of flux ropes in Mercury's magnetotail. Twenty‐eight flux ropes are obtained through the fitting to the non‐force‐free model. The flux ropes are found to be consistent with the flattened structures, in which the mean semimajor is ∼851 km and semiminor is ∼333 km, both are several times the local proton inertial length. The average core field is estimated to be ∼57.5 nT, and flux content is ∼0.019 MWb, much larger than the previous results obtained from force‐free flux rope model. The importance of thermal pressure gradient in the force balance of the flux ropes and the flattened structure indicates that the flux ropes in Mercury's magnetotail plasma sheet are mostly in early stage of the evolution, and still contain enough plasma to affect their magnetic structures.

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Section: Discussionsupporting

confidence: 90%

A Statistical Study of the Force Balance and Structure in the Flux Ropes in Mercury's Magnetotail

et al. 2019

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“…But it is still rare to see tailward jets beyond y =−1.0 R M or to see planetward jets beyond y =−0.5 R M . MESSENGER observed many such events far away from the midnight direction, such as the dipolarization fronts in Figure and statistics from other papers (Dewey et al, ; Sun et al, , ). This discrepancy may be simply caused by the varying IMF in the observations.…”

Section: Discussionmentioning

confidence: 63%

“…The MESSENGER observations of current sheet thickness (Poh et al, ), flux ropes, dipolarization events (Smith et al, ; Sun et al, , ), and energetic electron events (Dewey et al, ) do not and cannot distinguish the events under different IMF conditions. For the current sheet thickness observation, the current sheet sampling is almost uniform in time.…”

Section: Discussionmentioning

confidence: 99%

“…The dawnward drifting of the electrons may explain the energetic electrons dawn‐dusk asymmetry (Lindsay et al, ). However, the study of magnetic reconnection related magnetic structures, which are flux ropes and dipolarization fronts, in the near‐Mercury‐neutral‐line region showed both structures are also more frequently observed on the dawnside than on the duskside, which suggests the magnetic reconnection may prefer to happen on the dawnside and therefore created more energetic electrons in the postmidnight region than in the premidnight region (Sun et al, ; see also, Smith et al, ; Sun et al, ). The dawnside magnetic reconnection preferential occurrence in Mercury's plasma sheet is different from the observations in Earth's magnetosphere, where the magnetic reconnection‐related dynamic processes, such as the flux ropes (Imber et al, ) and dipolarization fronts (Liu et al, ), prefer the duskside plasma sheet.…”

Section: Introductionmentioning

confidence: 99%

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Studying Dawn‐Dusk Asymmetries of Mercury's Magnetotail Using MHD‐EPIC Simulations

et al. 2019

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MESSENGER has observed a lot of dawn-dusk asymmetries in Mercury's magnetotail, such as the asymmetries of the cross-tail current sheet thickness and the occurrence of flux ropes, dipolarization events, and energetic electron injections. In order to obtain a global pictures of Mercury's magnetotail dynamics and the relationship between these asymmetries, we perform global simulations with the magnetohydrodynamics with embedded particle-in-cell (MHD-EPIC) model, where Mercury's magnetotail region is covered by a PIC code. Our simulations show that the dawnside current sheet is thicker, the plasma density is larger, and the electron pressure is higher than the duskside. Under a strong interplanetary magnetic field driver, the simulated reconnection sites prefer the dawnside. We also found the dipolarization events and the planetward electron jets are moving dawnward while they are moving toward the planet, so that almost all dipolarization events and high-speed plasma flows concentrate in the dawn sector. The simulation results are consistent with MESSENGER observations.

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“…Smith et al () investigated the number of flux ropes observed during plasma sheet crossings, as well as the spacing between consecutive observations. The majority of crossings (61%) did not feature any flux ropes, while groups of up to eight were observed during periods of intense activity.…”

Section: Introductionmentioning

confidence: 99%

Evaluating Single‐Spacecraft Observations of Planetary Magnetotails With Simple Monte Carlo Simulations: 1. Spatial Distributions of the Neutral Line

et al. 2018

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A simple Monte Carlo model is presented that considers the effects of spacecraft orbital sampling on the inferred distribution of magnetic flux ropes, generated through magnetic reconnection in the magnetotail current sheet. When generalized, the model allows the determination of the number of orbits required to constrain the underlying population of structures: It is able to quantify this as a function of the physical parameters of the structures (e.g., azimuthal extent and probability of generation). The model is shown adapted to the Hermean magnetotail, where the outputs are compared to the results of a recent survey. This comparison suggests that the center of Mercury's neutral line is located dawnward of midnight by 0 3 and that the flux ropes are most likely to be wide azimuthally (∼50% of the width of the Hermean tail). The downtail location of the neutral line is not self‐consistent or in agreement with previous (independent) studies unless dissipation terms are included planetward of the reconnection site; potential physical explanations are discussed. In the future the model could be adapted to other environments, for example, the dayside magnetopause or other planetary magnetotails.

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Flux ropes in the Hermean magnetotail: Distribution, properties, and formation

Cited by 26 publications

References 78 publications

A Statistical Study of the Force Balance and Structure in the Flux Ropes in Mercury's Magnetotail

A Statistical Study of the Force Balance and Structure in the Flux Ropes in Mercury's Magnetotail

Studying Dawn‐Dusk Asymmetries of Mercury's Magnetotail Using MHD‐EPIC Simulations

Evaluating Single‐Spacecraft Observations of Planetary Magnetotails With Simple Monte Carlo Simulations: 1. Spatial Distributions of the Neutral Line

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