Impact of the Interplanetary Magnetic Field to Impingement of a Solar Wind Rotational Discontinuity on the Earth’s Bow Shock

Abstract. Field-aligned beams are known to originate from the quasi-perpendicular side of the Earth's bow shock, while the diffuse ion population consists of accelerated ions at the quasi-parallel side of the bow shock. The two distinct ion populations show typical characteristics in their velocity space distributions. By using particle and magnetic field measurements from one Cluster spacecraft we present a case study when the two ion populations are observed simultaneously in the foreshock region during a high Mach number, high solar wind velocity event. We present the spatial-temporal evolution of the field-aligned beam ion distribution in front of the Earth's bow shock, focusing on the processes in the deep foreshock region, i.e. on the quasi-parallel side. Our analysis demonstrates that the scattering of field-aligned beam (FAB) ions combined with convection by the solar wind results in the presence of lower-energy, toroidal gyrating ions at positions deeper in the foreshock region which are magnetically connected to the quasi-parallel bow shock. The gyrating ions are superposed onto a higher energy diffuse ion population. It is suggested that the toroidal gyrating ion population observed deep in the foreshock region has its origins in the FAB and that its characteristics are correlated with its distance from the FAB, but is independent on distance to the bow shock along the magnetic field.

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Plasma and Magnetic Field Turbulence in the Earth’s Magnetosheath at Ion Scales

Frontiers in Astronomy and Space Sciences ◽

10.3389/fspas.2020.616635 ◽

2021 ◽

Vol 7 ◽

Author(s):

Liudmila Rakhmanova ◽

Maria Riazantseva ◽

Georgy Zastenker

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Solar Wind Plasma ◽

Bow Shock ◽

Present Review ◽

Wind Effects ◽

Earth’S Bow Shock ◽

Magnetic Field Turbulence ◽

Plasma Measurements ◽

Turbulent Cascade

Crossing the Earth’s bow shock is known to crucially affect solar wind plasma including changes in turbulent cascade. The present review summarizes results of more than 15 years of experimental exploration into magnetosheath turbulence. Great contributions to understanding turbulence development inside the magnetosheath was made by means of recent multi-spacecraft missions. We introduce the main results provided by them together with first observations of the turbulent cascade based on direct plasma measurements by the Spektr-R spacecraft in the magnetosheath. Recent results on solar wind effects on turbulence in the magnetosheath are also discussed.

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Solar wind interaction with the Earth's magnetic field: 3. On the Earth's bow shock structure

Journal of Geophysical Research Atmospheres ◽

10.1029/ja078i019p03745 ◽

1973 ◽

Vol 78 (19) ◽

pp. 3745-3760 ◽

Cited By ~ 36

Author(s):

V. Formisano ◽

P. C. Hedgecock

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Shock Structure ◽

Bow Shock ◽

Earth’S Magnetic Field ◽

Solar Wind Interaction ◽

Earth’S Bow Shock ◽

Earth's Magnetic Field

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Venus's induced magnetosphere during active solar wind conditions at BepiColombo's Venus 1 flyby

10.5194/angeo-2021-24 ◽

2021 ◽

Author(s):

Martin Volwerk ◽

Beatriz Sánchez-Cano ◽

Daniel Heyner ◽

Sae Aizawa ◽

Nicolas André ◽

...

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Coronal Mass Ejection ◽

Interplanetary Magnetic Field ◽

Bow Shock ◽

Gravity Assist ◽

Highly Active ◽

Field Lines ◽

Mass Ejection ◽

The Magnetic Field

Abstract. Out of the two Venus flybys that BepiColombo uses as a gravity assist manoeuvre to finally arrive at Mercury, the first took place on 15 October 2020. After passing the bow shock, the spacecraft travelled along the induced magnetotail, crossing it mainly in the YVSO-direction. In this paper, the BepiColombo Mercury Planetary Orbiter Magnetometer (MPO-MAG) data are discussed, with support from three other plasma instruments: the Planetary Ion Camera (PICAM), the Mercury Electron Analyser (MEA) and the radiation monitor (BERM). Behind the bow shock crossing, the magnetic field showed a draping pattern consistent with field lines connected to the interplanetary magnetic field wrapping around the planet. This flyby showed a highly active magnetotail, with, e.g., strong flapping motions at a period of ~7 min. This activity was driven by solar wind conditions. Just before this flyby, Venus's induced magnetosphere was impacted by a stealth coronal mass ejection, of which the trailing side was still interacting with it during the flyby. This flyby is a unique opportunity to study the full length and structure of the induced magnetotail of Venus, indicating that the tail was most likely still present at about 48 Venus radii.

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Evidence for transient, local ion foreshocks caused by dayside magnetopause reconnection

Annales Geophysicae ◽

10.5194/angeo-34-943-2016 ◽

2016 ◽

Vol 34 (11) ◽

pp. 943-959 ◽

Cited By ~ 13

Author(s):

Yann Pfau-Kempf ◽

Heli Hietala ◽

Steve E. Milan ◽

Liisa Juusola ◽

Sanni Hoilijoki ◽

...

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Interplanetary Magnetic Field ◽

Ion Beams ◽

Bow Shock ◽

Flux Transfer Events ◽

Dayside Magnetopause ◽

Flux Transfer ◽

Push Out ◽

Magnetopause Reconnection

Abstract. We present a scenario resulting in time-dependent behaviour of the bow shock and transient, local ion reflection under unchanging solar wind conditions. Dayside magnetopause reconnection produces flux transfer events driving fast-mode wave fronts in the magnetosheath. These fronts push out the bow shock surface due to their increased downstream pressure. The resulting bow shock deformations lead to a configuration favourable to localized ion reflection and thus the formation of transient, travelling foreshock-like field-aligned ion beams. This is identified in two-dimensional global magnetospheric hybrid-Vlasov simulations of the Earth's magnetosphere performed using the Vlasiator model (http://vlasiator.fmi.fi). We also present observational data showing the occurrence of dayside reconnection and flux transfer events at the same time as Geotail observations of transient foreshock-like field-aligned ion beams. The spacecraft is located well upstream of the foreshock edge and the bow shock, during a steady southward interplanetary magnetic field and in the absence of any solar wind or interplanetary magnetic field perturbations. This indicates the formation of such localized ion foreshocks.

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Jets in the Magnetosheath: IMF Control of Where They Occur

10.5194/angeo-2019-65 ◽

2019 ◽

Author(s):

Laura Vuorinen ◽

Heli Hietala ◽

Ferdinand Plaschke

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Spatial Distribution ◽

Interplanetary Magnetic Field ◽

Cone Angle ◽

Time History ◽

Bow Shock ◽

The Earth ◽

Parallel Side ◽

History Of

Abstract. Magnetosheath jets are localized regions of plasma that move faster towards the Earth than the surrounding magnetosheath plasma. Due to their high velocities, they can cause indentations when colliding into the magnetopause and trigger processes such as magnetic reconnection and magnetopause surface waves. We statistically study the occurrence of these jets in the subsolar magnetosheath using measurements from the five Time History of Events and Macroscale Interactions during Substorms (THEMIS) spacecraft and OMNI solar wind data from 2008–2011. We present the observations in the BIMF-vSW plane and study the spatial distribution of jets during different interplanetary magnetic field (IMF) orientations. Jets occur downstream of the quasi-parallel bow shock approximately 9 times as often as downstream of the quasi-perpendicular shock, suggesting that foreshock processes are responsible for most jets. For oblique IMF, with 30°–60° cone angle, the occurrence increases monotonically from the quasi-perpendicular side to the quasi-parallel side. This study offers predictability for the numbers and locations of jets observed during different IMF orientations allowing us to better forecast the formation of these jets and their impact on the magnetosphere.

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Low-frequency magnetic variations at the high-<i>β</i> Earth bow shock

Annales Geophysicae ◽

10.5194/angeo-37-877-2019 ◽

2019 ◽

Vol 37 (5) ◽

pp. 877-889

Author(s):

Anatoli A. Petrukovich ◽

Olga M. Chugunova ◽

Pavel I. Shustov

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Spatial Scales ◽

Low Frequency ◽

Background Field ◽

Bow Shock ◽

Stable Phase ◽

Main Magnetic Field ◽

Astrophysical Plasmas ◽

Earth’S Bow Shock

Abstract. Observations of Earth's bow shock during high-β (ratio of thermal to magnetic pressure) solar wind streams are rare. However, such shocks are ubiquitous in astrophysical plasmas. Typical solar wind parameters related to high β (here β>10) are as follows: low speed, high density, and a very low interplanetary magnetic field of 1–2 nT. These conditions are usually quite transient and need to be verified immediately upstream of the observed shock crossings. In this report, three characteristic crossings by the Cluster project (from the 22 found) are studied using multipoint analysis, allowing us to determine spatial scales. The main magnetic field and density spatial scale of about a couple of hundred of kilometers generally corresponds to the increased proton convective gyroradius. Observed magnetic variations are different from those for supercritical shocks, with β∼1. Dominant magnetic variations in the shock transition have amplitudes much larger than the background field and have a frequency of ∼ 0.3–0.5 Hz (in some events – 1–2 Hz). The wave polarization has no stable phase and is closer to linear, which complicates the determination of the wave propagation direction. Spatial scales (wavelengths) of variations are within several tens to a couple of hundred of kilometers.

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Reflection of the strahl within the foot of the Earth's bow shock

Annales Geophysicae ◽

10.5194/angeo-37-243-2019 ◽

2019 ◽

Vol 37 (2) ◽

pp. 243-261 ◽

Cited By ~ 1

Author(s):

Christopher A. Gurgiolo ◽

Melvyn L. Goldstein ◽

Adolfo Viñas

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Free Energy ◽

Physical Properties ◽

Bow Shock ◽

Direct Connection ◽

Electron Reflection ◽

Primary Determinant ◽

Earth’S Bow Shock ◽

Wind Distribution

Abstract. The reflection of a fraction of the solar wind at the bow shock to some extent defines the physical properties of what is known as the foreshock, the region where the interplanetary magnetic field has a direct connection to the bow shock. Both ion and electron reflection have been observed and together form a significant source of free energy that is responsible for many of the instabilities observed in this region. In this paper we concentrate on the reflection of electrons at the shock and report two significant findings: the first is that the strahl, the field-aligned component of the electron solar wind distribution, appears to be fully reflected at the bow shock; the second finding is that the reflection is observed to occur in the foot of the shock and not in the shock ramp. This latter observation implies that mirroring in these examples is not the primary determinant of the electron reflection process.

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