Magnetic Holes Upstream of the Martian Bow Shock: MAVEN Observations

Madanian, Hadi; Halekas, J. S.; Mazelle, C.; Omidi, N.; Espley, J. R.; Mitchell, David; McFadden, J. P.

doi:10.1029/2019ja027198

Cited by 28 publications

(36 citation statements)

References 81 publications

(188 reference statements)

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“…The characteristics of the ubiquitous magnetic hole structures, that are indicative of temperature asymmetries in space plasmas, were studied just outside the Earth's bow shock (R ≥ 15R E ) with the MMS1 spacecraft. Naturally, due to the dynamics of the bow shock (see, for example, Meziane et al, 2014) 15R E may not suffice in some cases, which will then be magnetosheath structures. A test has been performed on the closest bin, 15 − 16R E , to see how many of the 22 events were in the magnetosheath, which resulted in only three events, all on the same day.…”

Section: Discussionmentioning

confidence: 99%

“…November 2017 through March 2018 and December 2018 through March 2019. An additional limit was set to the location of the spacecraft, namely that it be farther out than 15 R E , to avoid influence from the Earth's bow shock, which can move further outward in times of low solar wind pressure (Meziane et al, 2014). However this will not exclude the foreshock region from the data set, which extends much further upstream (Heppner et al, 1968;Greenstadt et al, 1968;Scarf et al, 1970).…”

Section: Instrumentation and Data Analysismentioning

confidence: 99%

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Statistical study of linear magnetic hole structures near Earth

et al. 2021

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Abstract. The Magnetospheric Multiscale mission (MMS1) data for 8 months in the winter periods of 2017–2018 and 2018–2019, when MMS had its apogee in the upstream solar wind of the Earth's bow shock, are used to study linear magnetic holes (LMHs). These LMHs are characterized by a magnetic depression of more than 50 % and a rotation of the background magnetic field of less then 10∘. A total of 406 LMHs are found and, based on their magnetoplasma characteristics, are split into three categories: cold (increase in density, little change in ion temperature), hot (increase in ion temperature, decrease in density) and sign change (at least one magnetic field component changes sign). The occurrence rate of LMHs is 2.3 per day. All LMHs are basically in pressure balance with the ambient plasma. Most of the linear magnetic holes are found in ambient plasmas that are stable against the mirror-mode generation, but only half of the holes are mirror-mode-stable inside.

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Section: Discussionmentioning

confidence: 99%

Section: Instrumentation and Data Analysismentioning

confidence: 99%

Statistical study of linear magnetic hole structures near Earth

et al. 2021

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“…The magnetic field data are from the Magnetometer sensor, which measures the magnetic field with up to 32 Hz sampling rate (Connerney et al, 2015). The ion data are from the Solar Wind Ion Analyzer (SWIA) instrument (Halekas et al, 2015), which measures ions in the 25 eV to 25 keV energy range with a 22.5° angular resolution over a total field of view of 2.8 π solid angle every 8 s. The ion moments are calculated in a similar way as in Halekas et al (2017) and Madanian et al (2019).…”

Section: Observationsmentioning

confidence: 99%

Nonstationary Quasiperpendicular Shock and Ion Reflection at Mars

Madanian

Schwartz

Halekas

et al. 2020

Geophysical Research Letters

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Collisionless shocks in space plasma are regions of heating and acceleration of charged particles and dissipation of kinetic energy. These accelerated particles are the source of electromagnetic emissions from supernova remnants and other astrophysical structures. At high Mach numbers, shocks can be inherently nonstationary and exhibit modulated energy transfer and recurring plasma compression areas in the form of reformation. We use data from the Mars Atmosphere and Volatile EvolutioN (MAVEN) spacecraft to study reformation of the Martian bow shock, which has a relatively high curvature compared to that at Earth, and the upstream solar wind is often mass loaded with a population of pickup ions. We show evidence of ion reflection effects in reformation of a supercritical quasiperpendicular shock.

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“…The temporal scale sizes of magnetic holes have been reported to vary between a few seconds and several minutes (Madanian et al., 2019; Sperveslage et al., 2000; Turner et al., 1977; Volwerk et al., 2020; Winterhalter et al., 1994; Xiao et al., 2010; Zhang, Russell, Baumjohann, et al., 2008). The variation of scale size with heliocentric distance is unclear.…”

Section: Introductionmentioning

confidence: 99%

Magnetic Holes in the Solar Wind and Magnetosheath Near Mercury

et al. 2021

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Solar wind magnetic holes were first reported by Turner et al. (1977) using magnetic field data from the Explorer 43 (IMP-6) spacecraft, and were defined as "isolated regions in the form of distinct depressions, or 'holes' in otherwise nearly average conditions." Such magnetic holes have since then been studied by many authors, at various heliocentric distances. We stress here that we will use the original definition of Turner et al. (1977) that the magnetic holes be isolated, and not a part of a quasi-periodic train as seen in observations of mirror mode waves (e.g.,

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Magnetic Holes Upstream of the Martian Bow Shock: MAVEN Observations

Cited by 28 publications

References 81 publications

Statistical study of linear magnetic hole structures near Earth

Statistical study of linear magnetic hole structures near Earth

Nonstationary Quasiperpendicular Shock and Ion Reflection at Mars

Magnetic Holes in the Solar Wind and Magnetosheath Near Mercury

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