Global ULF wave analysis of radial diffusion coefficients using a global MHD model for the 17 March 2015 storm

Zhao Li; Mary Hudson; Jan Paral; Michael Wiltberger; Drew Turner

doi:10.1002/2016JA022508

Global ULF wave analysis of radial diffusion coefficients using a global MHD model for the 17 March 2015 storm

Zhao Li, Mary Hudson, Jan Paral, Michael Wiltberger, Drew Turner

HAO Administrative Office

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30 Scopus citations

Abstract

The 17–18 March 2015 storm is the largest geomagnetic storm in the Van Allen Probes era to date. The Lyon-Fedder-Mobarry global MHD model has been run for this event using ARTEMIS data as solar wind input. The ULF wave power spectral density of the azimuthal electric field and compressional magnetic field is analyzed in the 0.5–8.3 mHz range. The lowest three azimuthal modes account for 70% of the total power during quiet times. However, during high activity, they are not exclusively dominant. The calculation of the radial diffusion coefficient is presented. We conclude that the electric field radial diffusion coefficient is dominant over the magnetic field coefficient by one to two orders of magnitude. This result contrasts with the dominant magnetic field diffusion coefficient used in most 3-D diffusion models.

Original language	English
Pages (from-to)	6196-6206
Number of pages	11
Journal	Journal of Geophysical Research: Space Physics
Volume	121
Issue number	7
DOIs	https://doi.org/10.1002/2016JA022508
State	Published - Jul 1 2016

Keywords

March 2015
ULF waves
radial diffusion
radial diffusion coefficient
radiation belt

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10.1002/2016JA022508

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title = "Global ULF wave analysis of radial diffusion coefficients using a global MHD model for the 17 March 2015 storm",

abstract = "The 17–18 March 2015 storm is the largest geomagnetic storm in the Van Allen Probes era to date. The Lyon-Fedder-Mobarry global MHD model has been run for this event using ARTEMIS data as solar wind input. The ULF wave power spectral density of the azimuthal electric field and compressional magnetic field is analyzed in the 0.5–8.3 mHz range. The lowest three azimuthal modes account for 70\% of the total power during quiet times. However, during high activity, they are not exclusively dominant. The calculation of the radial diffusion coefficient is presented. We conclude that the electric field radial diffusion coefficient is dominant over the magnetic field coefficient by one to two orders of magnitude. This result contrasts with the dominant magnetic field diffusion coefficient used in most 3-D diffusion models.",

keywords = "March 2015, ULF waves, radial diffusion, radial diffusion coefficient, radiation belt",

author = "Zhao Li and Mary Hudson and Jan Paral and Michael Wiltberger and Drew Turner",

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doi = "10.1002/2016JA022508",

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TY - JOUR

T1 - Global ULF wave analysis of radial diffusion coefficients using a global MHD model for the 17 March 2015 storm

AU - Li, Zhao

AU - Hudson, Mary

AU - Paral, Jan

AU - Wiltberger, Michael

AU - Turner, Drew

PY - 2016/7/1

Y1 - 2016/7/1

N2 - The 17–18 March 2015 storm is the largest geomagnetic storm in the Van Allen Probes era to date. The Lyon-Fedder-Mobarry global MHD model has been run for this event using ARTEMIS data as solar wind input. The ULF wave power spectral density of the azimuthal electric field and compressional magnetic field is analyzed in the 0.5–8.3 mHz range. The lowest three azimuthal modes account for 70% of the total power during quiet times. However, during high activity, they are not exclusively dominant. The calculation of the radial diffusion coefficient is presented. We conclude that the electric field radial diffusion coefficient is dominant over the magnetic field coefficient by one to two orders of magnitude. This result contrasts with the dominant magnetic field diffusion coefficient used in most 3-D diffusion models.

AB - The 17–18 March 2015 storm is the largest geomagnetic storm in the Van Allen Probes era to date. The Lyon-Fedder-Mobarry global MHD model has been run for this event using ARTEMIS data as solar wind input. The ULF wave power spectral density of the azimuthal electric field and compressional magnetic field is analyzed in the 0.5–8.3 mHz range. The lowest three azimuthal modes account for 70% of the total power during quiet times. However, during high activity, they are not exclusively dominant. The calculation of the radial diffusion coefficient is presented. We conclude that the electric field radial diffusion coefficient is dominant over the magnetic field coefficient by one to two orders of magnitude. This result contrasts with the dominant magnetic field diffusion coefficient used in most 3-D diffusion models.

KW - March 2015

KW - ULF waves

KW - radial diffusion

KW - radial diffusion coefficient

KW - radiation belt

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DO - 10.1002/2016JA022508

M3 - Article

AN - SCOPUS:84978100405

SN - 2169-9380

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JO - Journal of Geophysical Research: Space Physics

JF - Journal of Geophysical Research: Space Physics

IS - 7

ER -

Global ULF wave analysis of radial diffusion coefficients using a global MHD model for the 17 March 2015 storm

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Keywords

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