Wave-particle decorrelation and transport of anisotropic turbulence in collisionless plasmas

Z. Lin; I. Holod; L. Chen; P. H. Diamond; T. S. Hahm; S. Ethier

doi:10.1103/PhysRevLett.99.265003

Wave-particle decorrelation and transport of anisotropic turbulence in collisionless plasmas

Z. Lin, I. Holod, L. Chen, P. H. Diamond, T. S. Hahm, S. Ethier

PPPL Computational Science

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65 Scopus citations

Abstract

Comprehensive analysis of the largest first-principles simulations to date shows that stochastic wave-particle decorrelation is the dominant mechanism responsible for electron heat transport driven by electron temperature gradient turbulence with extended radial streamers. The transport is proportional to the local fluctuation intensity, and phase-space island overlap leads to a diffusive process with a time scale comparable to the wave-particle decorrelation time, determined by the fluctuation spectral width. This kinetic time scale is much shorter than the fluid time scale of eddy mixing.

Original language	English (US)
Article number	265003
Journal	Physical review letters
Volume	99
Issue number	26
DOIs	https://doi.org/10.1103/PhysRevLett.99.265003
State	Published - Dec 27 2007

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.99.265003

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AU - Lin, Z.

AU - Holod, I.

AU - Chen, L.

AU - Diamond, P. H.

AU - Hahm, T. S.

AU - Ethier, S.

PY - 2007/12/27

Y1 - 2007/12/27

N2 - Comprehensive analysis of the largest first-principles simulations to date shows that stochastic wave-particle decorrelation is the dominant mechanism responsible for electron heat transport driven by electron temperature gradient turbulence with extended radial streamers. The transport is proportional to the local fluctuation intensity, and phase-space island overlap leads to a diffusive process with a time scale comparable to the wave-particle decorrelation time, determined by the fluctuation spectral width. This kinetic time scale is much shorter than the fluid time scale of eddy mixing.

AB - Comprehensive analysis of the largest first-principles simulations to date shows that stochastic wave-particle decorrelation is the dominant mechanism responsible for electron heat transport driven by electron temperature gradient turbulence with extended radial streamers. The transport is proportional to the local fluctuation intensity, and phase-space island overlap leads to a diffusive process with a time scale comparable to the wave-particle decorrelation time, determined by the fluctuation spectral width. This kinetic time scale is much shorter than the fluid time scale of eddy mixing.

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ER -

Wave-particle decorrelation and transport of anisotropic turbulence in collisionless plasmas

Abstract

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