Multipoint Observations of Quasiperiodic Emission Intensification and Effects on Energetic Electron Precipitation

Jinxing Li; Jacob Bortnik; Qianli Ma; Wen Li; Xiaochen Shen; Yukitoshi Nishimura; Xin An; Scott Thaller; Aaron Breneman; John Wygant; William S. Kurth; George B. Hospodarsky; David P. Hartley; Geoffrey D. Reeves; Herbert O. Funsten; J. Bernard Blake; Harlan Spence; Daniel N. Baker

doi:10.1029/2020JA028484

Multipoint Observations of Quasiperiodic Emission Intensification and Effects on Energetic Electron Precipitation

Jinxing Li, Jacob Bortnik, Qianli Ma, Wen Li, Xiaochen Shen, Yukitoshi Nishimura, Xin An, Scott Thaller, Aaron Breneman, John Wygant, William S. Kurth, George B. Hospodarsky, David P. Hartley, Geoffrey D. Reeves, Herbert O. Funsten, J. Bernard Blake, Harlan Spence, Daniel N. Baker

Physics and Astronomy (Twin Cities)

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Abstract

The two Van Allen Probes simultaneously recorded a coherently modulated quasiperiodic (QP) emission that persisted for 3 h. The magnetic field pulsation at the locations of the two satellites showed a substantial difference, and their frequencies were close to but did not exactly match the repetition frequency of QP emissions for most of the time, suggesting that those coherent QP emissions probably originated from a common source, which then propagated over a broad area in the magnetosphere. The QP emissions were amplified by local anisotropic electron distributions, and their large-scale amplitudes were modulated by the plasma density. A novel observation of this event is that chorus waves at frequencies above QP emissions exhibit a strong correlation with QP emissions. Those chorus waves intensified when the QP emissions reach their peak frequency. This indicates that embryonic QP emissions may be critical for its own intensification as well as chorus waves under certain circumstances. A Low-Earth-Orbit POES satellite observed enhanced energetic electron precipitation in conjunction with the Van Allen Probes, providing direct evidence that QP emissions precipitate energetic electrons into the atmosphere. This scenario is quantitatively confirmed by our quasilinear diffusion simulation results.

Original language	English (US)
Article number	e2020JA028484
Journal	Journal of Geophysical Research: Space Physics
Volume	126
Issue number	2
DOIs	https://doi.org/10.1029/2020JA028484
State	Published - Feb 2021

Bibliographical note

Funding Information:
J. Li, J. Bortnik, and X. An acknowledge the NSF grant AGS-1923126 and NASA grant LWS-80NSSC20K0201. J. Li and J. Bortnik acknowledge the grant DE-SC0010578 and NASA grants 80NSSC18K1227, and NNX14AI18G. Q. Ma would like to acknowledge the NASA grant 80NSSC20K0196 and 80NSSC19K0844. W. Li acknowledges the NASA grants 80NSSC17K0231, 80NSSC19K0845, and 80NSSC20K0698, NSF grants AGS-1723588 and AGS-1847818, as well as the Alfred P. Sloan Research Fellowship FG-2018-10936. This work was supported by the RBSP-ECT and EMFISIS funding provided by JHU/APL contract No. 967399 and 921647 under NASA's prime contract No. NAS5-01072.

Publisher Copyright:
© 2021. American Geophysical Union. All Rights Reserved.

Keywords

ULF wave
Van Allen Probes
chorus waves
electron precipitation
quasiperiodic emissions
radiation belt

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Li, J., Bortnik, J., Ma, Q., Li, W., Shen, X., Nishimura, Y., An, X., Thaller, S., Breneman, A., Wygant, J., Kurth, W. S., Hospodarsky, G. B., Hartley, D. P., Reeves, G. D., Funsten, H. O., Blake, J. B., Spence, H., & Baker, D. N. (2021). Multipoint Observations of Quasiperiodic Emission Intensification and Effects on Energetic Electron Precipitation. Journal of Geophysical Research: Space Physics, 126(2), Article e2020JA028484. https://doi.org/10.1029/2020JA028484

Li, J, Bortnik, J, Ma, Q, Li, W, Shen, X, Nishimura, Y, An, X, Thaller, S, Breneman, A, Wygant, J, Kurth, WS, Hospodarsky, GB, Hartley, DP, Reeves, GD, Funsten, HO, Blake, JB, Spence, H & Baker, DN 2021, 'Multipoint Observations of Quasiperiodic Emission Intensification and Effects on Energetic Electron Precipitation', Journal of Geophysical Research: Space Physics, vol. 126, no. 2, e2020JA028484. https://doi.org/10.1029/2020JA028484

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title = "Multipoint Observations of Quasiperiodic Emission Intensification and Effects on Energetic Electron Precipitation",

abstract = "The two Van Allen Probes simultaneously recorded a coherently modulated quasiperiodic (QP) emission that persisted for 3 h. The magnetic field pulsation at the locations of the two satellites showed a substantial difference, and their frequencies were close to but did not exactly match the repetition frequency of QP emissions for most of the time, suggesting that those coherent QP emissions probably originated from a common source, which then propagated over a broad area in the magnetosphere. The QP emissions were amplified by local anisotropic electron distributions, and their large-scale amplitudes were modulated by the plasma density. A novel observation of this event is that chorus waves at frequencies above QP emissions exhibit a strong correlation with QP emissions. Those chorus waves intensified when the QP emissions reach their peak frequency. This indicates that embryonic QP emissions may be critical for its own intensification as well as chorus waves under certain circumstances. A Low-Earth-Orbit POES satellite observed enhanced energetic electron precipitation in conjunction with the Van Allen Probes, providing direct evidence that QP emissions precipitate energetic electrons into the atmosphere. This scenario is quantitatively confirmed by our quasilinear diffusion simulation results.",

keywords = "ULF wave, Van Allen Probes, chorus waves, electron precipitation, quasiperiodic emissions, radiation belt",

author = "Jinxing Li and Jacob Bortnik and Qianli Ma and Wen Li and Xiaochen Shen and Yukitoshi Nishimura and Xin An and Scott Thaller and Aaron Breneman and John Wygant and Kurth, {William S.} and Hospodarsky, {George B.} and Hartley, {David P.} and Reeves, {Geoffrey D.} and Funsten, {Herbert O.} and Blake, {J. Bernard} and Harlan Spence and Baker, {Daniel N.}",

note = "Funding Information: J. Li, J. Bortnik, and X. An acknowledge the NSF grant AGS-1923126 and NASA grant LWS-80NSSC20K0201. J. Li and J. Bortnik acknowledge the grant DE-SC0010578 and NASA grants 80NSSC18K1227, and NNX14AI18G. Q. Ma would like to acknowledge the NASA grant 80NSSC20K0196 and 80NSSC19K0844. W. Li acknowledges the NASA grants 80NSSC17K0231, 80NSSC19K0845, and 80NSSC20K0698, NSF grants AGS-1723588 and AGS-1847818, as well as the Alfred P. Sloan Research Fellowship FG-2018-10936. This work was supported by the RBSP-ECT and EMFISIS funding provided by JHU/APL contract No. 967399 and 921647 under NASA's prime contract No. NAS5-01072. Publisher Copyright: {\textcopyright} 2021. American Geophysical Union. All Rights Reserved.",

year = "2021",

month = feb,

doi = "10.1029/2020JA028484",

language = "English (US)",

volume = "126",

journal = "Journal of Geophysical Research: Space Physics",

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AU - Li, Jinxing

AU - Bortnik, Jacob

AU - Ma, Qianli

AU - Li, Wen

AU - Shen, Xiaochen

AU - Nishimura, Yukitoshi

AU - An, Xin

AU - Thaller, Scott

AU - Breneman, Aaron

AU - Wygant, John

AU - Kurth, William S.

AU - Hospodarsky, George B.

AU - Hartley, David P.

AU - Reeves, Geoffrey D.

AU - Funsten, Herbert O.

AU - Blake, J. Bernard

AU - Spence, Harlan

AU - Baker, Daniel N.

N1 - Funding Information: J. Li, J. Bortnik, and X. An acknowledge the NSF grant AGS-1923126 and NASA grant LWS-80NSSC20K0201. J. Li and J. Bortnik acknowledge the grant DE-SC0010578 and NASA grants 80NSSC18K1227, and NNX14AI18G. Q. Ma would like to acknowledge the NASA grant 80NSSC20K0196 and 80NSSC19K0844. W. Li acknowledges the NASA grants 80NSSC17K0231, 80NSSC19K0845, and 80NSSC20K0698, NSF grants AGS-1723588 and AGS-1847818, as well as the Alfred P. Sloan Research Fellowship FG-2018-10936. This work was supported by the RBSP-ECT and EMFISIS funding provided by JHU/APL contract No. 967399 and 921647 under NASA's prime contract No. NAS5-01072. Publisher Copyright: © 2021. American Geophysical Union. All Rights Reserved.

PY - 2021/2

Y1 - 2021/2

N2 - The two Van Allen Probes simultaneously recorded a coherently modulated quasiperiodic (QP) emission that persisted for 3 h. The magnetic field pulsation at the locations of the two satellites showed a substantial difference, and their frequencies were close to but did not exactly match the repetition frequency of QP emissions for most of the time, suggesting that those coherent QP emissions probably originated from a common source, which then propagated over a broad area in the magnetosphere. The QP emissions were amplified by local anisotropic electron distributions, and their large-scale amplitudes were modulated by the plasma density. A novel observation of this event is that chorus waves at frequencies above QP emissions exhibit a strong correlation with QP emissions. Those chorus waves intensified when the QP emissions reach their peak frequency. This indicates that embryonic QP emissions may be critical for its own intensification as well as chorus waves under certain circumstances. A Low-Earth-Orbit POES satellite observed enhanced energetic electron precipitation in conjunction with the Van Allen Probes, providing direct evidence that QP emissions precipitate energetic electrons into the atmosphere. This scenario is quantitatively confirmed by our quasilinear diffusion simulation results.

AB - The two Van Allen Probes simultaneously recorded a coherently modulated quasiperiodic (QP) emission that persisted for 3 h. The magnetic field pulsation at the locations of the two satellites showed a substantial difference, and their frequencies were close to but did not exactly match the repetition frequency of QP emissions for most of the time, suggesting that those coherent QP emissions probably originated from a common source, which then propagated over a broad area in the magnetosphere. The QP emissions were amplified by local anisotropic electron distributions, and their large-scale amplitudes were modulated by the plasma density. A novel observation of this event is that chorus waves at frequencies above QP emissions exhibit a strong correlation with QP emissions. Those chorus waves intensified when the QP emissions reach their peak frequency. This indicates that embryonic QP emissions may be critical for its own intensification as well as chorus waves under certain circumstances. A Low-Earth-Orbit POES satellite observed enhanced energetic electron precipitation in conjunction with the Van Allen Probes, providing direct evidence that QP emissions precipitate energetic electrons into the atmosphere. This scenario is quantitatively confirmed by our quasilinear diffusion simulation results.

KW - ULF wave

KW - Van Allen Probes

KW - chorus waves

KW - electron precipitation

KW - quasiperiodic emissions

KW - radiation belt

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ER -

Multipoint Observations of Quasiperiodic Emission Intensification and Effects on Energetic Electron Precipitation

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Keywords

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