Multipoint observations of plasma phenomena made in space by Cluster

Goldstein, M. L.; Escoubet, Philippe; Hwang, Kyoung‐Joo; Wendel, D. E.; Viñas, A. F.; Fung, S. F.; Perri, S.; Servidio, S.; Pickett, J. S.; Parks, G. K.; Sahraoui, Fouad; Gurgiolo, C.; Matthaeus, W. H.; Weygand, J. M.

doi:10.1017/s0022377815000185

Cited by 19 publications

(15 citation statements)

References 381 publications

(571 reference statements)

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“…The standard method for describing the parts of the magnetic power spectrum is via an energy‐cascade picture. Sketches of the cascade concept of the solar wind magnetic spectrum can be found in Figure 19 of Goldstein et al (), Figure 2 of Howes (), and Figure 14of Matthaeus et al (). The first column of Figure lists the main concepts used in that method of describing the solar wind's magnetic power spectrum.…”

Section: Discussionmentioning

confidence: 99%

On the Fourier Contribution of Strong Current Sheets to the High‐Frequency Magnetic Power SpectralDensity of the Solar Wind

Borovsky

Burkholder

2020

JGR Space Physics

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The hypothesis is explored that the high‐frequency magnetic spectral power of the solar wind is associated with the spatial profiles of strong current sheets (directional discontinuities) in the solar wind plasma. This hypothesis is based on previous findings about current sheets and the solar wind's magnetic power spectra (1) that the amplitude distribution and waiting time distribution of strong current sheets determines the amplituic composition and the electron strade and spectral slope of the “inertial range” of frequencies and (2) that the thicknesses of strong current sheets in the solar wind determine the breakpoint frequency that ends the inertial range. Solar wind current sheets are collected from the WIND 0.09375‐s and MMS 7.8 × 10−3‐s magnetic data sets, and the current sheets are individually Fourier transformed. At frequencies above the solar wind breakpoint (1) the shape of the magnetic power spectra of the current sheets resembles the shape of the magnetic power spectra of the solar wind and (2) the current sheets occur frequently enough to account for the magnetic power of the solar wind above the breakpoint. This has implications for the physics underlying the high‐frequency magnetic power spectral density of the solar wind, supplementing the energy‐cascade description of the high‐frequency spectrum.

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Section: Discussionmentioning

confidence: 99%

On the Fourier Contribution of Strong Current Sheets to the High‐Frequency Magnetic Power SpectralDensity of the Solar Wind

Borovsky

Burkholder

2020

JGR Space Physics

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“…The characteristic scales at which this break-down occurs are given by the proton gyro-radius ρ p = v th,p /Ω p (being v th,p the proton thermal speed and Ω p the proton gyrofrequency) and/or the proton skin depth d p = c/ω cp (being c the speed of light and ω cp the proton plasma frequency) [2,[4][5][6]. At these scales the dynamics could be mediated by kinetic-Alfvén fluctuations, whistler-like perturbations and coherent structures such as vortexes and current sheets [7].The most narrow current sheets and filaments are present at electron scales, where turbulent energy eventually dissipates [8,9], even if the energy-dissipation mechanisms in a weakly-collisional plasma such as the turbulent solar wind are far from being understood. Recent kinetic simulations…”

mentioning

confidence: 99%

“…The most narrow current sheets and filaments are present at electron scales, where turbulent energy eventually dissipates [8,9], even if the energy-dissipation mechanisms in a weakly-collisional plasma such as the turbulent solar wind are far from being understood. Recent kinetic simulations…”

mentioning

confidence: 99%

“…Magnetic reconnection is the change of topology of the magnetic field, with subsequent conversion of energy into flows, heat, and non-thermal effects. Usually, reconnection and turbulence have been studied as separate topics, but more recently it has been suggested that these effects might coexist [7,9,14]. Namely, reconnection of thin current sheets can take place in magnetohydrodynamics (MHD), as well as in plasma-kinetic models [10].…”

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confidence: 99%

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The Complex Structure of Magnetic Field Discontinuities in the Turbulent Solar Wind

Greco

Perri

Servidio

et al. 2016

ApJL

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Using high resolution Cluster satellite observations, we show that the turbulent solar wind is populated by magnetic discontinuities at different scales, going from proton down to electron scales. The structure of these layers resembles the Harris equilibrium profile in plasmas. Using a multi-dimensional intermittency technique, we show that these structures are connected through the scales. Supported by numerical simulations of magnetic reconnection, we show that observations are consistent with a scenario where many current layers develop in turbulence, and where the outflow of these reconnection events are characterized by complex sub-proton networks of secondary islands, in a self-similar way. The present work establishes that the picture of "reconnection in turbulence" and "turbulent reconnection", separately invoked as ubiquitous, coexist in space plasmas.In the past decades, spacecraft observations suggested that plasma turbulence shares many similarities with classical hydrodynamics. The power spectrum of magnetic field fluctuations as a function of frequencies f manifests an inertial range, with a Kolmogorov-like scaling f −5/3 (see for example Ref . [1]). More recently, high resolution measurements revealed the presence of a secondary inertial sub-range, where the spectrum breaks down and exhibits a power index steeper than −5/3 [2, 3]. The characteristic scales at which this break-down occurs are given by the proton gyro-radius ρ p = v th,p /Ω p (being v th,p the proton thermal speed and Ω p the proton gyrofrequency) and/or the proton skin depth d p = c/ω cp (being c the speed of light and ω cp the proton plasma frequency) [2,[4][5][6]. At these scales the dynamics could be mediated by kinetic-Alfvén fluctuations, whistler-like perturbations and coherent structures such as vortexes and current sheets [7].The most narrow current sheets and filaments are present at electron scales, where turbulent energy eventually dissipates [8,9], even if the energy-dissipation mechanisms in a weakly-collisional plasma such as the turbulent solar wind are far from being understood. Recent kinetic simulations

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“…The spin‐integrated differential particle flux in cm −2 s −1 sr −1 keV −1 as a function of time is shown in Figure a. Density ( n ) and heat flux parallel to the magnetic field ( H || ) were calculated using a trapezoidal integration scheme that was validated against existing Cluster moments code [ Goldstein et al , ] and are shown in Figures b and c, respectively. From reported N(v) and f ( v ) values, the covariance matrix was calculated following section 2.…”

Section: Uncertainties From Cluster/peacementioning

confidence: 99%

The calculation of moment uncertainties from velocity distribution functions with random errors

et al. 2015

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Instrumentation that detects individual plasma particles is susceptible to random counting errors. These errors propagate into the calculations of moments of measured particle velocity distribution functions. Although rules of thumb exist for the effects of random errors on the calculation of lower order moments (e.g., density, velocity, and temperature) of Maxwell-Boltzmann distributions, they do not generally apply to nonthermal distributions or to higher-order moments. To date, such errors have only been estimated using brute force Monte Carlo techniques, i.e., repeated (~50) samplings of distribution functions. Here we present a mathematical formalism for analytically obtaining uncertainty estimates of plasma moments due to random errors either measured in situ by instruments or synthesized by particle simulations. Our uncertainty estimates precisely match the statistical variation of simulated plasma moments and carry the computational cost equivalent of only~15 Monte Carlo samplings. In addition, we provide the means to calculate a covariance matrix that can be reported along with typical plasma moments. This matrix enables the propagation of statistical errors into arbitrary coordinate systems or functions of plasma moments without the need to reanalyze full distribution functions. Our methodology, which is applied to electron data from Plasma Electron and Current Experiment on the Cluster spacecraft as an example, is relevant to both existing and future data sets and requires only instrument-measured counts and phase space densities reported for a set of calibrated energy-angle targets.

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Multipoint observations of plasma phenomena made in space by Cluster

Cited by 19 publications

References 381 publications

On the Fourier Contribution of Strong Current Sheets to the High‐Frequency Magnetic Power SpectralDensity of the Solar Wind

On the Fourier Contribution of Strong Current Sheets to the High‐Frequency Magnetic Power SpectralDensity of the Solar Wind

The Complex Structure of Magnetic Field Discontinuities in the Turbulent Solar Wind

The calculation of moment uncertainties from velocity distribution functions with random errors

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