M. L. Goldstein scite author profile

Electron scale solar wind turbulence has attracted great interest in recent years. Clear evidences have been given from the Cluster data that turbulence is not fully dissipated near the proton scale but continues cascading down to the electron scales. However, the scaling of the energy spectra as well as the nature of the plasma modes involved at those small scales are still not fully determined. Here we survey 10 years of the Cluster search-coil magnetometer (SCM) waveforms measured in the solar wind and perform a statistical study of the magnetic energy spectra in the frequency range [1, 180]Hz. We show that a large fraction of the spectra exhibit clear breakpoints near the electron gyroscale ρ e , followed by steeper power-law like spectra. We show that the scaling below the electron breakpoint cannot be determined unambiguously due to instrumental limitations that will be discussed in detail. We compare our results to those reported in other studies and discuss their implication on the physical mechanisms and the theoretical modeling of energy dissipation in the SW.

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The nature and evolution of magnetohydrodynamic fluctuations in the solar wind: Voyager observations

Roberts¹,

Klein²,

Goldstein³

et al. 1987

J. Geophys. Res.

262

183

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Energy deposition by Alfvén waves into the dayside auroral oval: Cluster and FAST observations

et al. 2005

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[1] We report in situ observations from the Cluster and FAST spacecraft showing the deposition of energy into the auroral ionosphere from broadband ULF waves in the cusp and low-latitude boundary layer. A comparison of the wave Poynting flux with particle energy and flux at both satellites indicates that energy transfer from the broadband waves to the plasma occurs through field-aligned electron acceleration, transverse ion acceleration, and Joule heating. These processes are shown to result in precipitating electron fluxes sufficient to drive bright aurora and cause outflows of energized electrons and O + ions from the ionosphere into the low-latitude boundary layer. By solving an eigenmode equation for Alfvén waves in the observed plasma environment, it is shown that the broadband waves observed at Cluster and FAST are dispersive Alfvén waves. It is demonstrated that these waves have wavelengths perpendicular to the geomagnetic field extending from significant fractions of an L shell down to ion gyroradii and electron inertial lengths and wave frequencies in the plasma frame from 1 mHz up to 50 mHz. These waves are shown to have wavelengths along the geomagnetic field of the order of the field line length between the ionosphere and the equatorial plane and become field line resonances (FLRs) when on closed field lines. It is shown that the inclusion of nonlinear and/or nonlocal kinetic effects is required in the description of these waves to account for accelerated particles observed. On the basis of the wave polarization and spectral properties observed from Cluster and FAST it is speculated that these waves are generated through the mode conversion of surface Alfvén waves driven by tailward flows in the low-latitude boundary layer.Citation: Chaston, C. C., et al. (2005), Energy deposition by Alfvén waves into the dayside auroral oval: Cluster and FAST observations,

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Cosmic ray modulation and turbulent interaction regions near 11 AU

Burlaga¹,

McDonald²,

Goldstein³

et al. 1985

J. Geophys. Res.

200

111

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When Voyager 2 was near 11 AU, the counting rate of nuclei N 75 MeV/nucleon decreased during the interval from July, 1982 to November, 1982, and it increased thereafter until August, 1983. The counting rate fluctuated within this I'minicycle" with short term decreases lasting 1 to 4 days and recoveries lasting several days. A decrease in cosmic ray flux was generally associated with the passage of an "interaction region" in which the magnetic field strength B was higher than that predicted by the spiral field model, Bp . Several large enhancements in B/B p were associated with "merged interaction regions" which probably resulted from the interaction of two or more distinct flows. During the passage of interaction regions the cosmic ray intensity decreased at a rate proportional to (B/Bp -1), and during the passage of rarefaction regions (where B/B p < 1) the cosmic ray intensity increased at a constant rate. The general form of the cosmic ray intensity profile during this s 13 month I'minicycle" can be described by integrating these relations using the observed B(t), and it can be understood in terms of the sizes and separations of interaction regions. Latitudinal variations of the interaction regions and of the short-term cosmic ray variations were identified by comparing Voyager 2 observations with Voyager 1 observations made at higher latitudes O V to 200 ). The interaction regions were turbulent, with an f -5/3 spectrum from at least 3 x 10 -4 Hz to f 0 to 2) x 10 -6 Hz. A break in the spectrum at f corresponds to the characteristic width of the interaction regions, and it represents a "stirring scale" for the solar wind. The interaction regions, including merged interaction regions, may be viewed as "turbulent boundary layers" which grow in size with increasing distance from the sun.They act as barriers which impede the net flow of cosmic rays toward the sun.2

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Properties of magnetohydrodynamic turbulence in the solar wind as observed by Ulysses at high heliographic latitudes

Goldstein

Smith

Balogh

et al. 1995

Geophysical Research Letters

137

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The Ulysses mission provides an opportunity to study the evolution of magnetohydrodynamic (MHD) turbulence in pure high‐speed solar wind streams. The absence at high heliocentric latitudes of the strong shears in solar wind velocity generally present near the heliocentric current sheet allows investigation of how fluctuations in the magnetic field and plasma relax and evolve in the radially expanding solar wind. We report results of an analysis of the radial and latitudinal variation of the turbulence properties of the fluctuations, especially various plasma‐field correlations, in high latitude regions. The results constrain current theories of the evolution of MHD turbulence in the solar wind. Compared to similar observations at 0.3 AU by Helios, we find spectra that are similar in having a large frequency band with an f¹ power spectrum in the outward traveling component of the waves, followed at higher frequencies by a steeper spectrum. Ulysses observations establish that at high latitudes the turbulence is less evolved (i.e., has a smaller inertial range) than it is in the ecliptic at the same heliocentric distance, apparently due to the absence of strong velocity shear. Once Ulysses is in the polar coronal hole, properties of the turbulence appear to be determined by the heliocentric distance of the spacecraft rather than by its helio‐latitude.

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M. L. Goldstein

Scaling of the Electron Dissipation Range of Solar Wind Turbulence

The nature and evolution of magnetohydrodynamic fluctuations in the solar wind: Voyager observations

Energy deposition by Alfvén waves into the dayside auroral oval: Cluster and FAST observations

Cosmic ray modulation and turbulent interaction regions near 11 AU

Properties of magnetohydrodynamic turbulence in the solar wind as observed by Ulysses at high heliographic latitudes

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