Higher-Order Statistics in Compressive Solar Wind Plasma Turbulence: High-Resolution Density Observations From the Magnetospheric MultiScale Mission

<p>Turbulent density fluctuations are investigated in the solar wind at sub-ion scales using calibrated spacecraft potential. The measurement technique using the spacecraft potential allows for a much higher time resolution and sensitivity when compared to direct measurements using plasma instruments. Using this novel method, density fluctuations can be measured with unprecedentedly high time resolutions for in situ measurements of solar wind plasma at 1 a.u. By investigating 1 h of high-time resolution data, the scale dependant kurtosis is calculated by varying the time lag &#964; to calculate increments between observations. The scale-dependent kurtosis is found to increase towards ion scales but then plateaus and remains fairly constant through the sub-ion range in a similar fashion to magnetic field measurements. The sub-ion range is also found to exhibit self-similar monofractal behavior contrasting sharply with the multi-fractal behavior at large scales. The scale-dependent kurtosis is also calculated using increments between two different spacecraft. When the time lags are converted using the ion bulk velocity to a comparable spatial lag, a discrepancy is observed between the two measurement techniques. Several different possibilities are discussed including a breakdown of Taylor&#8217;s hypothesis, high-frequency plasma waves, or intrinsic differences between sampling directions.</p>

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Structure of the Front of a Collisionless Oblique Interplanetary Shock Wave from High Time Resolution Measurements of Solar-Wind Plasma Parameters

Geomagnetism and Aeronomy ◽

10.1134/s001679321806004x ◽

2018 ◽

Vol 58 (6) ◽

pp. 728-736

Author(s):

V. G. Eselevich ◽

N. L. Borodkova ◽

O. V. Sapunova ◽

G. N. Zastenker ◽

Yu. I. Yermolaev

Keyword(s):

Shock Wave ◽

Solar Wind ◽

Time Resolution ◽

Solar Wind Plasma ◽

Interplanetary Shock ◽

High Time ◽

High Time Resolution ◽

Plasma Parameters ◽

Interplanetary Shock Wave

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Are there current-sheet-like structures in the Earth's magnetotail as in the solar wind – results and implications from high time resolution magnetic field measurements by Cluster

Annales Geophysicae ◽

10.5194/angeo-26-1889-2008 ◽

2008 ◽

Vol 26 (7) ◽

pp. 1889-1895 ◽

Cited By ~ 13

Author(s):

G. Li ◽

E. Lee ◽

G. Parks

Keyword(s):

Magnetic Field ◽

Solar Wind ◽

Current Sheet ◽

Time Resolution ◽

Field Measurements ◽

Solar Wind Plasma ◽

High Time ◽

High Time Resolution ◽

Mhd Turbulence ◽

Flux Tubes

Abstract. Recent studies of solar wind MHD turbulence show that current-sheet-like structures are common in the solar wind and they are a significant source of solar wind MHD turbulence intermittency. While numerical simulations have suggested that such structures can arise from non-linear interactions of MHD turbulence, a recent study by Borovsky (2006), upon analyzing one year worth of ACE data, suggests that these structures may represent the magnetic walls of flux tubes that separate solar wind plasma into distinct bundles and these flux tubes are relic structures originating from boundaries of supergranules on the surface of the Sun. In this work, we examine whether there are such structures in the Earth's magnetotail, an environment vastly different from the solar wind. We use high time resolution magnetic field data of the FGM instrument onboard Cluster C1 spacecraft. The orbits of Cluster traverse through both the solar wind and the Earth's magnetosheath and magnetotail. This makes its dataset ideal for studying differences between solar wind MHD turbulence and that inside the Earth's magnetosphere. For comparison, we also perform the same analysis when Cluster C1 is in the solar wind. Using a data analysis procedure first introduced in Li (2007, 2008), we find that current-sheet-like structures can be clearly identified in the solar wind. However, similar structures do not exist inside the Earth's magnetotail. This result can be naturally explained if these structures have a solar origin as proposed by Borovsky (2006). With such a scenario, current analysis of solar wind MHD turbulence needs to be improved to include the effects due to these curent-sheet-like structures.

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Fine structure of the interplanetary shock front according to measurements of the ion flux of the solar wind with high time resolution

Cosmic Research ◽

10.1134/s0010952517010038 ◽

2017 ◽

Vol 55 (1) ◽

pp. 30-45 ◽

Cited By ~ 6

Author(s):

V. G. Eselevich ◽

N. L. Borodkova ◽

M. V. Eselevich ◽

G. N. Zastenker ◽

Y. Šafránkova ◽

...

Keyword(s):

Solar Wind ◽

Fine Structure ◽

Shock Front ◽

Time Resolution ◽

Interplanetary Shock ◽

Ion Flux ◽

High Time ◽

High Time Resolution

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Short-term Fluctuations Of The Mesospheric Na Layer Observed By High-time-resolution Lidar

E3S Web of Conferences ◽

10.1051/e3sconf/20185301016 ◽

2018 ◽

Vol 53 ◽

pp. 01016

Author(s):

Xiaodong Wang ◽

Fan Yi

Keyword(s):

Gravity Wave ◽

Time Resolution ◽

Characteristic Time ◽

Density Fluctuations ◽

High Time ◽

High Time Resolution ◽

Short Term ◽

Lidar Measurements ◽

The Mean

Based on the 6-s resolution Na lidar measurements during ~395 hours on 47 different nights from May to November 2011 in Beijing(40.2°N, 116°E), China, it was found that the Na density at altitude 83-98 km always exhibited strong short-term fluctuations. The magnitude of the mean absolute increasing and decreasing rates for these short-term fluctuations ranged from ~8 to ~16 cm-3s-1. Their profiles were close to each other with the increasing rate being slightly larger than that of decreasing rate at most altitudes. This difference coincided with the earlier observations that the Na layer column abundance mostly tends to have a slow net increase during night [2]. The characteristic time for the short-term Na density fluctuations had a magnitude ranging from 46 to 118 s at altitudes between 83 and 98 km, which was apparently shorter than the Brunt-Väisälä period (~5 min). The gravity wave seems difficultly to induce observed Na fluctuations.

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A high time resolution study of the solar wind-magnetosphere energy coupling function

Planetary and Space Science ◽

10.1016/0032-0633(82)90162-3 ◽

1982 ◽

Vol 30 (6) ◽

pp. 537-543 ◽

Cited By ~ 12

Author(s):

S.-I. Akasofu ◽

J.F. Carbary ◽

C.-I. Meng ◽

J.P. Sullivan ◽

R.P. Lepping

Keyword(s):

Solar Wind ◽

Time Resolution ◽

Energy Coupling ◽

Coupling Function ◽

High Time ◽

High Time Resolution ◽

Resolution Study

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Magnetopause boundary structure deduced from the high-time resolution particle experiment on the Equator-S spacecraft

Annales Geophysicae ◽

10.1007/s00585-999-1574-3 ◽

1999 ◽

Vol 17 (12) ◽

pp. 1574-1581 ◽

Cited By ~ 1

Author(s):

G. K. Parks ◽

S. Datta ◽

M. McCarthy ◽

R. P. Lin ◽

H. Reme ◽

...

Keyword(s):

Solar Wind ◽

Time Resolution ◽

Boundary Region ◽

Control Device ◽

Electron Energy Spectrum ◽

Wind Pressure ◽

High Time ◽

Boundary Structure ◽

High Time Resolution ◽

Magnetospheric Configuration And Dynamics

Abstract. An electrostatic analyser (ESA) onboard the Equator-S spacecraft operating in coordination with a potential control device (PCD) has obtained the first accurate electron energy spectrum with energies ≈7 eV–100 eV in the vicinity of the magnetopause. On 8 January, 1998, a solar wind pressure increase pushed the magnetopause inward, leaving the Equator-S spacecraft in the magnetosheath. On the return into the magnetosphere approximately 80 min later, the magnetopause was observed by the ESA and the solid state telescopes (the SSTs detected electrons and ions with energies ≈20–300 keV). The high time resolution (3 s) data from ESA and SST show the boundary region contains of multiple plasma sources that appear to evolve in space and time. We show that electrons with energies ≈7 eV–100 eV permeate the outer regions of the magnetosphere, from the magnetopause to ≈6Re. Pitch-angle distributions of ≈20–300 keV electrons show the electrons travel in both directions along the magnetic field with a peak at 90° indicating a trapped configuration. The IMF during this interval was dominated by Bx and By components with a small Bz.Key words. Magnetospheric physics (magnetopause · cusp · and boundary layers; magnetospheric configuration and dynamics; solar wind · magnetosphere interactions)

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