On the Turbulent Reduction of Drifts for Solar Energetic Particles

On the Turbulent Reduction of Drifts for Solar Energetic Particles

Abstract Particle drifts perpendicular to the background magnetic field have been proposed by some authors as an explanation for the very efficient perpendicular transport of solar energetic particles (SEPs). This process, however, competes with perpendicular diffusion caused by magnetic turbulence,...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 922; no. 2; pp. 200 - 214
Main Authors: van den Berg, J. P., Engelbrecht, N. E., Wijsen, N., Strauss, R. D.
Format: Journal Article
Language:English
Published: Philadelphia The American Astronomical Society 01-12-2021
IOP Publishing
Subjects:
Astrophysics
Cosmic rays
Diffusion
Diffusion coefficient
Drift
Energetic particles
Heliosphere
Interplanetary turbulence
Magnetic fields
Pitch (inclination)
Reduction
Solar energetic particles
Solar wind
Turbulence
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Summary:Abstract Particle drifts perpendicular to the background magnetic field have been proposed by some authors as an explanation for the very efficient perpendicular transport of solar energetic particles (SEPs). This process, however, competes with perpendicular diffusion caused by magnetic turbulence, which can also disrupt the drift patterns and reduce the magnitude of drift effects. The latter phenomenon is well known in cosmic-ray studies, but not yet considered in SEP models. Additionally, SEP models that do not include drifts, especially for electrons, use turbulent drift reduction as a justification of this omission, without critically evaluating or testing this assumption. This article presents the first theoretical step for a theory of drift suppression in SEP transport. This is done by deriving the turbulence-dependent drift reduction function with a pitch-angle dependence, as is applicable for anisotropic particle distributions, and by investigating to what extent drifts will be reduced in the inner heliosphere for realistic turbulence conditions and different pitch-angle dependencies of the perpendicular diffusion coefficient. The influence of the derived turbulent drift reduction factors on the transport of SEPs are tested, using a state-of-the-art SEP transport code, for several expressions of theoretically derived perpendicular diffusion coefficients. It is found, for realistic turbulence conditions in the inner heliosphere, that cross-field diffusion will have the largest influence on the perpendicular transport of SEPs, as opposed to particle drifts.
Bibliography:The Sun and the Heliosphere
AAS33033
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ac2736