Space–time structure and wavevector anisotropy in space plasma turbulence

Abstract Space and astrophysical plasmas often develop into a turbulent state and exhibit nearly random and stochastic motions. While earlier studies emphasize more on understanding the energy spectrum of turbulence in the one-dimensional context (either in the frequency or the wavenumber domain), r...

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Main Author: Yasuhito Narita
Format: Article
Language:English
Published: SpringerOpen 2018-02-01
Series:Living Reviews in Solar Physics
Subjects:
Online Access:http://link.springer.com/article/10.1007/s41116-017-0010-0
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spelling doaj-d609fa7293d8495c88f2ca11ea8551612020-11-24T22:05:35ZengSpringerOpenLiving Reviews in Solar Physics2367-36481614-49612018-02-0115114810.1007/s41116-017-0010-0Space–time structure and wavevector anisotropy in space plasma turbulenceYasuhito Narita0Space Research Institute, Austrian Academy of SciencesAbstract Space and astrophysical plasmas often develop into a turbulent state and exhibit nearly random and stochastic motions. While earlier studies emphasize more on understanding the energy spectrum of turbulence in the one-dimensional context (either in the frequency or the wavenumber domain), recent achievements in plasma turbulence studies provide an increasing amount of evidence that plasma turbulence is essentially a spatially and temporally evolving phenomenon. This review presents various models for the space–time structure and anisotropy of the turbulent fields in space plasmas, or equivalently the energy spectra in the wavenumber–frequency domain for the space–time structures and that in the wavevector domain for the anisotropies. The turbulence energy spectra are evaluated in different one-dimensional spectral domains; one speaks of the frequency spectra in the spacecraft observations and the wavenumber spectra in the numerical simulation studies. The notion of the wavenumber–frequency spectrum offers a more comprehensive picture of the turbulent fields, and good models can explain the one-dimensional spectra in the both domains at the same time. To achieve this goal, the Doppler shift, the Doppler broadening, linear-mode dispersion relations, and sideband waves are reviewed. The energy spectra are then extended to the wavevector domain spanning the directions parallel and perpendicular to the large-scale magnetic field. By doing so, the change in the spectral index at different projections onto the one-dimensional spectral domain can be explained in a simpler way.http://link.springer.com/article/10.1007/s41116-017-0010-0Dispersion relationAnisotropySolar wind turbulence
collection DOAJ
language English
format Article
sources DOAJ
author Yasuhito Narita
spellingShingle Yasuhito Narita
Space–time structure and wavevector anisotropy in space plasma turbulence
Living Reviews in Solar Physics
Dispersion relation
Anisotropy
Solar wind turbulence
author_facet Yasuhito Narita
author_sort Yasuhito Narita
title Space–time structure and wavevector anisotropy in space plasma turbulence
title_short Space–time structure and wavevector anisotropy in space plasma turbulence
title_full Space–time structure and wavevector anisotropy in space plasma turbulence
title_fullStr Space–time structure and wavevector anisotropy in space plasma turbulence
title_full_unstemmed Space–time structure and wavevector anisotropy in space plasma turbulence
title_sort space–time structure and wavevector anisotropy in space plasma turbulence
publisher SpringerOpen
series Living Reviews in Solar Physics
issn 2367-3648
1614-4961
publishDate 2018-02-01
description Abstract Space and astrophysical plasmas often develop into a turbulent state and exhibit nearly random and stochastic motions. While earlier studies emphasize more on understanding the energy spectrum of turbulence in the one-dimensional context (either in the frequency or the wavenumber domain), recent achievements in plasma turbulence studies provide an increasing amount of evidence that plasma turbulence is essentially a spatially and temporally evolving phenomenon. This review presents various models for the space–time structure and anisotropy of the turbulent fields in space plasmas, or equivalently the energy spectra in the wavenumber–frequency domain for the space–time structures and that in the wavevector domain for the anisotropies. The turbulence energy spectra are evaluated in different one-dimensional spectral domains; one speaks of the frequency spectra in the spacecraft observations and the wavenumber spectra in the numerical simulation studies. The notion of the wavenumber–frequency spectrum offers a more comprehensive picture of the turbulent fields, and good models can explain the one-dimensional spectra in the both domains at the same time. To achieve this goal, the Doppler shift, the Doppler broadening, linear-mode dispersion relations, and sideband waves are reviewed. The energy spectra are then extended to the wavevector domain spanning the directions parallel and perpendicular to the large-scale magnetic field. By doing so, the change in the spectral index at different projections onto the one-dimensional spectral domain can be explained in a simpler way.
topic Dispersion relation
Anisotropy
Solar wind turbulence
url http://link.springer.com/article/10.1007/s41116-017-0010-0
work_keys_str_mv AT yasuhitonarita spacetimestructureandwavevectoranisotropyinspaceplasmaturbulence
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