Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations

Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations

Context. In 2020 May-June, six solar energetic ion events were observed by the Parker Solar Probe/IS IS instrument suite at ≈0.35 AU from the Sun. From standard velocity-dispersion analysis, the apparent ion path length is ≈0.625 AU at the onset of each event. Aims. We develop a formalism for estima...

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Main Authors: R. Chhiber, W. H. Matthaeus, C. M.S. Cohen, D. Ruffolo, W. Sonsrettee, P. Tooprakai, A. Seripienlert, P. Chuychai, A. V. Usmanov, M. L. Goldstein, D. J. McComas, R. A. Leske, J. R. Szalay, C. J. Joyce, A. C. Cummings, E. C. Roelof, E. R. Christian, R. A. Mewaldt, A. W. Labrador, J. Giacalone, N. A. Schwadron, D. G. Mitchell, M. E. Hill, M. E. Wiedenbeck, R. L. McNutt, M. I. Desai
Other Authors: California Institute of Technology
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Published: 2022
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Earth and Planetary Sciences
Physics and Astronomy
Online Access:https://repository.li.mahidol.ac.th/handle/123456789/76861
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spelling th-mahidol.768612022-08-04T18:26:52Z Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations R. Chhiber W. H. Matthaeus C. M.S. Cohen D. Ruffolo W. Sonsrettee P. Tooprakai A. Seripienlert P. Chuychai A. V. Usmanov M. L. Goldstein D. J. McComas R. A. Leske J. R. Szalay C. J. Joyce A. C. Cummings E. C. Roelof E. R. Christian R. A. Mewaldt A. W. Labrador J. Giacalone N. A. Schwadron D. G. Mitchell M. E. Hill M. E. Wiedenbeck R. L. McNutt M. I. Desai California Institute of Technology Chulalongkorn University University of New Hampshire Durham University of Maryland, Baltimore County (UMBC) Johns Hopkins University Applied Physics Laboratory Mahidol University The University of Arizona Jet Propulsion Laboratory NASA Goddard Space Flight Center Princeton University The University of Texas at San Antonio The Bartol Research Institute National Astronomical Research Institute of Thailand Panyapiwat Institute of Management Earth and Planetary Sciences Physics and Astronomy Context. In 2020 May-June, six solar energetic ion events were observed by the Parker Solar Probe/IS IS instrument suite at ≈0.35 AU from the Sun. From standard velocity-dispersion analysis, the apparent ion path length is ≈0.625 AU at the onset of each event. Aims. We develop a formalism for estimating the path length of random-walking magnetic field lines to explain why the apparent ion path length at an event onset greatly exceeds the radial distance from the Sun for these events. Methods. We developed analytical estimates of the average increase in path length of random-walking magnetic field lines, relative to the unperturbed mean field. Monte Carlo simulations of field line and particle trajectories in a model of solar wind turbulence were used to validate the formalism and study the path lengths of particle guiding-center and full-orbital trajectories. The formalism was implemented in a global solar wind model, and the results are compared with ion path lengths inferred from IS IS observations. Results. Both a simple estimate and a rigorous theoretical formulation are obtained for field-lines' path length increase as a function of path length along the large-scale field. From simulated field line and particle trajectories, we find that particle guiding centers can have path lengths somewhat shorter than the average field line path length, while particle orbits can have substantially longer path lengths due to their gyromotion with a nonzero effective pitch angle. Conclusions. The long apparent path length during these solar energetic ion events can be explained by (1) a magnetic field line path length increase due to the field line random walk and (2) particle transport about the guiding center with a nonzero effective pitch angle due to pitch angle scattering. Our formalism for computing the magnetic field line path length, accounting for turbulent fluctuations, may be useful for application to solar particle transport in general. 2022-08-04T08:32:20Z 2022-08-04T08:32:20Z 2021-06-01 Article Astronomy and Astrophysics. Vol.650, (2021) 10.1051/0004-6361/202039816 14320746 00046361 2-s2.0-85107395647 https://repository.li.mahidol.ac.th/handle/123456789/76861 Mahidol University SCOPUS https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85107395647&origin=inward
institution Mahidol University
building Mahidol University Library
continent Asia
country Thailand
Thailand
content_provider Mahidol University Library
collection Mahidol University Institutional Repository
topic Earth and Planetary Sciences
Physics and Astronomy
spellingShingle Earth and Planetary Sciences
Physics and Astronomy
R. Chhiber
W. H. Matthaeus
C. M.S. Cohen
D. Ruffolo
W. Sonsrettee
P. Tooprakai
A. Seripienlert
P. Chuychai
A. V. Usmanov
M. L. Goldstein
D. J. McComas
R. A. Leske
J. R. Szalay
C. J. Joyce
A. C. Cummings
E. C. Roelof
E. R. Christian
R. A. Mewaldt
A. W. Labrador
J. Giacalone
N. A. Schwadron
D. G. Mitchell
M. E. Hill
M. E. Wiedenbeck
R. L. McNutt
M. I. Desai
Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations
description Context. In 2020 May-June, six solar energetic ion events were observed by the Parker Solar Probe/IS IS instrument suite at ≈0.35 AU from the Sun. From standard velocity-dispersion analysis, the apparent ion path length is ≈0.625 AU at the onset of each event. Aims. We develop a formalism for estimating the path length of random-walking magnetic field lines to explain why the apparent ion path length at an event onset greatly exceeds the radial distance from the Sun for these events. Methods. We developed analytical estimates of the average increase in path length of random-walking magnetic field lines, relative to the unperturbed mean field. Monte Carlo simulations of field line and particle trajectories in a model of solar wind turbulence were used to validate the formalism and study the path lengths of particle guiding-center and full-orbital trajectories. The formalism was implemented in a global solar wind model, and the results are compared with ion path lengths inferred from IS IS observations. Results. Both a simple estimate and a rigorous theoretical formulation are obtained for field-lines' path length increase as a function of path length along the large-scale field. From simulated field line and particle trajectories, we find that particle guiding centers can have path lengths somewhat shorter than the average field line path length, while particle orbits can have substantially longer path lengths due to their gyromotion with a nonzero effective pitch angle. Conclusions. The long apparent path length during these solar energetic ion events can be explained by (1) a magnetic field line path length increase due to the field line random walk and (2) particle transport about the guiding center with a nonzero effective pitch angle due to pitch angle scattering. Our formalism for computing the magnetic field line path length, accounting for turbulent fluctuations, may be useful for application to solar particle transport in general.
author2 California Institute of Technology
author_facet California Institute of Technology
R. Chhiber
W. H. Matthaeus
C. M.S. Cohen
D. Ruffolo
W. Sonsrettee
P. Tooprakai
A. Seripienlert
P. Chuychai
A. V. Usmanov
M. L. Goldstein
D. J. McComas
R. A. Leske
J. R. Szalay
C. J. Joyce
A. C. Cummings
E. C. Roelof
E. R. Christian
R. A. Mewaldt
A. W. Labrador
J. Giacalone
N. A. Schwadron
D. G. Mitchell
M. E. Hill
M. E. Wiedenbeck
R. L. McNutt
M. I. Desai
format Article
author R. Chhiber
W. H. Matthaeus
C. M.S. Cohen
D. Ruffolo
W. Sonsrettee
P. Tooprakai
A. Seripienlert
P. Chuychai
A. V. Usmanov
M. L. Goldstein
D. J. McComas
R. A. Leske
J. R. Szalay
C. J. Joyce
A. C. Cummings
E. C. Roelof
E. R. Christian
R. A. Mewaldt
A. W. Labrador
J. Giacalone
N. A. Schwadron
D. G. Mitchell
M. E. Hill
M. E. Wiedenbeck
R. L. McNutt
M. I. Desai
author_sort R. Chhiber
title Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations
title_short Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations
title_full Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations
title_fullStr Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations
title_full_unstemmed Magnetic field line random walk and solar energetic particle path lengths: Stochastic theory and PSP/IS IS observations
title_sort magnetic field line random walk and solar energetic particle path lengths: stochastic theory and psp/is is observations
publishDate 2022
url https://repository.li.mahidol.ac.th/handle/123456789/76861
_version_ 1763488810437443584

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