The relationship between the plasmapause and outer belt electrons

J. Goldstein; D. N. Baker; J. B. Blake; S. De Pascuale; H. O. Funsten; A. N. Jaynes; J. M. Jahn; C. A. Kletzing; W. S. Kurth; W. Li; G. D. Reeves; H. E. Spence

doi:10.1002/2016JA023046

The relationship between the plasmapause and outer belt electrons

J. Goldstein, D. N. Baker, J. B. Blake, S. De Pascuale, H. O. Funsten, A. N. Jaynes, J. M. Jahn, C. A. Kletzing, W. S. Kurth, W. Li, G. D. Reeves, H. E. Spence

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20 Scopus citations

Abstract

We quantify the spatial relationship between the plasmapause and outer belt electrons for a 5 day period, 15–20 January 2013, by comparing locations of relativistic electron flux peaks to the plasmapause. A peak-finding algorithm is applied to 1.8–7.7 MeV relativistic electron flux data. A plasmapause gradient finder is applied to wave-derived electron number densities >10 cm⁻³. We identify two outer belts. Outer belt 1 is a stable zone of >3 MeV electrons located 1–2 R_E inside the plasmapause. Outer belt 2 is a dynamic zone of <3 MeV electrons within 0.5 R_E of the moving plasmapause. Electron fluxes earthward of each belt's peak are anticorrelated with cold plasma density. Belt 1 decayed on hiss timescales prior to a disturbance on 17 January and suffered only a modest dropout, perhaps owing to shielding by the plasmasphere. Afterward, the partially depleted belt 1 continued to decay at the initial rate. Belt 2 was emptied out by strong disturbance-time losses but restored within 24 h. For global context we use a plasmapause test particle simulation and derive a new plasmaspheric index F_p, the fraction of a circular drift orbit inside the plasmapause. We find that the locally measured plasmapause is (for this event) a good proxy for the globally integrated opportunity for losses in cold plasma. Our analysis of the 15–20 January 2013 time interval confirms that high-energy electron storage rings can persist for weeks or even months if prolonged quiet conditions prevail. This case study must be followed up by more general study (not limited to a 5 day period).

Original language	English
Pages (from-to)	8392-8416
Number of pages	25
Journal	Journal of Geophysical Research: Space Physics
Volume	121
Issue number	9
DOIs	https://doi.org/10.1002/2016JA023046
State	Published - Sep 1 2016
Externally published	Yes

Funding

Van Allen Probes data (and plasmapause test particle simulations) are publicly accessible via the ECT and EMFISIS links at http://rbspgway.jhuapl.edu/. OMNI solar wind data are accessible via http://cdaweb.gsfc.nasa.gov/. HEO 3 data are available at http://virbo.org/HEO. This work was supported primarily by RBSP-ECT funding provided by JHU/APL contract 967399 under NASA's prime contract NAS5-01072. Development of the F

Keywords

Van Allen Probes
plasmapause
plasmaspheric hiss
radiation belts
simulation
storm-time dropouts

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10.1002/2016JA023046

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@article{388b3c90abc4419089eb6280bf046475,

title = "The relationship between the plasmapause and outer belt electrons",

abstract = "We quantify the spatial relationship between the plasmapause and outer belt electrons for a 5 day period, 15–20 January 2013, by comparing locations of relativistic electron flux peaks to the plasmapause. A peak-finding algorithm is applied to 1.8–7.7 MeV relativistic electron flux data. A plasmapause gradient finder is applied to wave-derived electron number densities >10 cm−3. We identify two outer belts. Outer belt 1 is a stable zone of >3 MeV electrons located 1–2 RE inside the plasmapause. Outer belt 2 is a dynamic zone of <3 MeV electrons within 0.5 RE of the moving plasmapause. Electron fluxes earthward of each belt's peak are anticorrelated with cold plasma density. Belt 1 decayed on hiss timescales prior to a disturbance on 17 January and suffered only a modest dropout, perhaps owing to shielding by the plasmasphere. Afterward, the partially depleted belt 1 continued to decay at the initial rate. Belt 2 was emptied out by strong disturbance-time losses but restored within 24 h. For global context we use a plasmapause test particle simulation and derive a new plasmaspheric index Fp, the fraction of a circular drift orbit inside the plasmapause. We find that the locally measured plasmapause is (for this event) a good proxy for the globally integrated opportunity for losses in cold plasma. Our analysis of the 15–20 January 2013 time interval confirms that high-energy electron storage rings can persist for weeks or even months if prolonged quiet conditions prevail. This case study must be followed up by more general study (not limited to a 5 day period).",

keywords = "Van Allen Probes, plasmapause, plasmaspheric hiss, radiation belts, simulation, storm-time dropouts",

author = "J. Goldstein and Baker, \{D. N.\} and Blake, \{J. B.\} and \{De Pascuale\}, S. and Funsten, \{H. O.\} and Jaynes, \{A. N.\} and Jahn, \{J. M.\} and Kletzing, \{C. A.\} and Kurth, \{W. S.\} and W. Li and Reeves, \{G. D.\} and Spence, \{H. E.\}",

year = "2016",

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T1 - The relationship between the plasmapause and outer belt electrons

AU - Goldstein, J.

AU - Baker, D. N.

AU - Blake, J. B.

AU - De Pascuale, S.

AU - Funsten, H. O.

AU - Jaynes, A. N.

AU - Jahn, J. M.

AU - Kletzing, C. A.

AU - Kurth, W. S.

AU - Li, W.

AU - Reeves, G. D.

AU - Spence, H. E.

PY - 2016/9/1

Y1 - 2016/9/1

N2 - We quantify the spatial relationship between the plasmapause and outer belt electrons for a 5 day period, 15–20 January 2013, by comparing locations of relativistic electron flux peaks to the plasmapause. A peak-finding algorithm is applied to 1.8–7.7 MeV relativistic electron flux data. A plasmapause gradient finder is applied to wave-derived electron number densities >10 cm−3. We identify two outer belts. Outer belt 1 is a stable zone of >3 MeV electrons located 1–2 RE inside the plasmapause. Outer belt 2 is a dynamic zone of <3 MeV electrons within 0.5 RE of the moving plasmapause. Electron fluxes earthward of each belt's peak are anticorrelated with cold plasma density. Belt 1 decayed on hiss timescales prior to a disturbance on 17 January and suffered only a modest dropout, perhaps owing to shielding by the plasmasphere. Afterward, the partially depleted belt 1 continued to decay at the initial rate. Belt 2 was emptied out by strong disturbance-time losses but restored within 24 h. For global context we use a plasmapause test particle simulation and derive a new plasmaspheric index Fp, the fraction of a circular drift orbit inside the plasmapause. We find that the locally measured plasmapause is (for this event) a good proxy for the globally integrated opportunity for losses in cold plasma. Our analysis of the 15–20 January 2013 time interval confirms that high-energy electron storage rings can persist for weeks or even months if prolonged quiet conditions prevail. This case study must be followed up by more general study (not limited to a 5 day period).

AB - We quantify the spatial relationship between the plasmapause and outer belt electrons for a 5 day period, 15–20 January 2013, by comparing locations of relativistic electron flux peaks to the plasmapause. A peak-finding algorithm is applied to 1.8–7.7 MeV relativistic electron flux data. A plasmapause gradient finder is applied to wave-derived electron number densities >10 cm−3. We identify two outer belts. Outer belt 1 is a stable zone of >3 MeV electrons located 1–2 RE inside the plasmapause. Outer belt 2 is a dynamic zone of <3 MeV electrons within 0.5 RE of the moving plasmapause. Electron fluxes earthward of each belt's peak are anticorrelated with cold plasma density. Belt 1 decayed on hiss timescales prior to a disturbance on 17 January and suffered only a modest dropout, perhaps owing to shielding by the plasmasphere. Afterward, the partially depleted belt 1 continued to decay at the initial rate. Belt 2 was emptied out by strong disturbance-time losses but restored within 24 h. For global context we use a plasmapause test particle simulation and derive a new plasmaspheric index Fp, the fraction of a circular drift orbit inside the plasmapause. We find that the locally measured plasmapause is (for this event) a good proxy for the globally integrated opportunity for losses in cold plasma. Our analysis of the 15–20 January 2013 time interval confirms that high-energy electron storage rings can persist for weeks or even months if prolonged quiet conditions prevail. This case study must be followed up by more general study (not limited to a 5 day period).

KW - Van Allen Probes

KW - plasmapause

KW - plasmaspheric hiss

KW - radiation belts

KW - simulation

KW - storm-time dropouts

UR - https://www.scopus.com/pages/publications/84987934309

U2 - 10.1002/2016JA023046

DO - 10.1002/2016JA023046

M3 - Article

AN - SCOPUS:84987934309

SN - 2169-9380

VL - 121

SP - 8392

EP - 8416

JO - Journal of Geophysical Research: Space Physics

JF - Journal of Geophysical Research: Space Physics

IS - 9

ER -

The relationship between the plasmapause and outer belt electrons

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