Local Excitation of Whistler Mode Waves and Associated Langmuir Waves at Dayside Reconnection Regions

Jinxing Li; Jacob Bortnik; Xin An; Wen Li; Christopher T. Russell; Meng Zhou; Jean Berchem; Cong Zhao; Shan Wang; Roy B. Torbert; Olivier Le Contel; Robert E. Ergun; Per Arne Lindqvist; Craig J. Pollock; James L. Burch

doi:10.1029/2018GL078287

Local Excitation of Whistler Mode Waves and Associated Langmuir Waves at Dayside Reconnection Regions

Jinxing Li
, Jacob Bortnik
, Xin An
, Wen Li
, Christopher T. Russell
, Meng Zhou
, Jean Berchem
, Cong Zhao
, Shan Wang
, Roy B. Torbert
, Olivier Le Contel
, Robert E. Ergun
, Per Arne Lindqvist
, Craig J. Pollock
, James L. Burch

Research output: Contribution to journal › Article › peer-review

Abstract

In the Earth's dayside reconnection boundary layer, whistler mode waves coincide with magnetic field openings and the formation of the resultant anisotropic electrons. Depending on the energy range of anisotropic electrons, whistlers can grow at frequencies in the upper and/or lower band. Observations show that whistler mode waves modulate Langmuir wave amplitude as they propagate toward the X line. Observations of whistler mode wave phase and Langmuir waves packets, as well as coincident electron measurements, reveal that whistler mode waves can accelerate electrons via Landau resonance at locations where E_||is antiparallel to the wave propagation direction. The accelerated electrons produce localized beams, which subsequently drive the periodically modulated Langmuir waves. The close association of those two wave modes reveals the microscale electron dynamics in the exhaust region, and the proposed mechanism could potentially be applied to explain the modulation events observed in planetary magnetospheres and in the solar wind.

Original language	English
Pages (from-to)	8793-8802
Number of pages	10
Journal	Geophysical Research Letters
Volume	45
Issue number	17
DOIs	https://doi.org/10.1029/2018GL078287
Publication status	Published - 16 Sept 2018
Externally published	Yes

Keywords

Langmuir wave
dayside reconnection
magnetopause
nonlinear interaction
wave-particle interaction
whistler mode wave

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10.1029/2018GL078287

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Li, J., Bortnik, J., An, X., Li, W., Russell, C. T., Zhou, M., Berchem, J., Zhao, C., Wang, S., Torbert, R. B., Le Contel, O., Ergun, R. E., Lindqvist, P. A., Pollock, C. J., & Burch, J. L. (2018). Local Excitation of Whistler Mode Waves and Associated Langmuir Waves at Dayside Reconnection Regions. Geophysical Research Letters, 45(17), 8793-8802. https://doi.org/10.1029/2018GL078287

@article{aef49fd47a0346c69eadaa1015d56312,

title = "Local Excitation of Whistler Mode Waves and Associated Langmuir Waves at Dayside Reconnection Regions",

abstract = "In the Earth's dayside reconnection boundary layer, whistler mode waves coincide with magnetic field openings and the formation of the resultant anisotropic electrons. Depending on the energy range of anisotropic electrons, whistlers can grow at frequencies in the upper and/or lower band. Observations show that whistler mode waves modulate Langmuir wave amplitude as they propagate toward the X line. Observations of whistler mode wave phase and Langmuir waves packets, as well as coincident electron measurements, reveal that whistler mode waves can accelerate electrons via Landau resonance at locations where E||is antiparallel to the wave propagation direction. The accelerated electrons produce localized beams, which subsequently drive the periodically modulated Langmuir waves. The close association of those two wave modes reveals the microscale electron dynamics in the exhaust region, and the proposed mechanism could potentially be applied to explain the modulation events observed in planetary magnetospheres and in the solar wind.",

keywords = "Langmuir wave, dayside reconnection, magnetopause, nonlinear interaction, wave-particle interaction, whistler mode wave",

author = "Jinxing Li and Jacob Bortnik and Xin An and Wen Li and Russell, \{Christopher T.\} and Meng Zhou and Jean Berchem and Cong Zhao and Shan Wang and Torbert, \{Roy B.\} and \{Le Contel\}, Olivier and Ergun, \{Robert E.\} and Lindqvist, \{Per Arne\} and Pollock, \{Craig J.\} and Burch, \{James L.\}",

year = "2018",

month = sep,

day = "16",

doi = "10.1029/2018GL078287",

language = "English",

volume = "45",

pages = "8793--8802",

journal = "Geophysical Research Letters",

issn = "0094-8276",

number = "17",

}

Li, J, Bortnik, J, An, X, Li, W, Russell, CT, Zhou, M, Berchem, J, Zhao, C, Wang, S, Torbert, RB, Le Contel, O, Ergun, RE, Lindqvist, PA, Pollock, CJ & Burch, JL 2018, 'Local Excitation of Whistler Mode Waves and Associated Langmuir Waves at Dayside Reconnection Regions', Geophysical Research Letters, vol. 45, no. 17, pp. 8793-8802. https://doi.org/10.1029/2018GL078287

TY - JOUR

T1 - Local Excitation of Whistler Mode Waves and Associated Langmuir Waves at Dayside Reconnection Regions

AU - Li, Jinxing

AU - Bortnik, Jacob

AU - An, Xin

AU - Li, Wen

AU - Russell, Christopher T.

AU - Zhou, Meng

AU - Berchem, Jean

AU - Zhao, Cong

AU - Wang, Shan

AU - Torbert, Roy B.

AU - Le Contel, Olivier

AU - Ergun, Robert E.

AU - Lindqvist, Per Arne

AU - Pollock, Craig J.

AU - Burch, James L.

PY - 2018/9/16

Y1 - 2018/9/16

N2 - In the Earth's dayside reconnection boundary layer, whistler mode waves coincide with magnetic field openings and the formation of the resultant anisotropic electrons. Depending on the energy range of anisotropic electrons, whistlers can grow at frequencies in the upper and/or lower band. Observations show that whistler mode waves modulate Langmuir wave amplitude as they propagate toward the X line. Observations of whistler mode wave phase and Langmuir waves packets, as well as coincident electron measurements, reveal that whistler mode waves can accelerate electrons via Landau resonance at locations where E||is antiparallel to the wave propagation direction. The accelerated electrons produce localized beams, which subsequently drive the periodically modulated Langmuir waves. The close association of those two wave modes reveals the microscale electron dynamics in the exhaust region, and the proposed mechanism could potentially be applied to explain the modulation events observed in planetary magnetospheres and in the solar wind.

AB - In the Earth's dayside reconnection boundary layer, whistler mode waves coincide with magnetic field openings and the formation of the resultant anisotropic electrons. Depending on the energy range of anisotropic electrons, whistlers can grow at frequencies in the upper and/or lower band. Observations show that whistler mode waves modulate Langmuir wave amplitude as they propagate toward the X line. Observations of whistler mode wave phase and Langmuir waves packets, as well as coincident electron measurements, reveal that whistler mode waves can accelerate electrons via Landau resonance at locations where E||is antiparallel to the wave propagation direction. The accelerated electrons produce localized beams, which subsequently drive the periodically modulated Langmuir waves. The close association of those two wave modes reveals the microscale electron dynamics in the exhaust region, and the proposed mechanism could potentially be applied to explain the modulation events observed in planetary magnetospheres and in the solar wind.

KW - Langmuir wave

KW - dayside reconnection

KW - magnetopause

KW - nonlinear interaction

KW - wave-particle interaction

KW - whistler mode wave

UR - https://www.scopus.com/pages/publications/85053369711

U2 - 10.1029/2018GL078287

DO - 10.1029/2018GL078287

M3 - Article

AN - SCOPUS:85053369711

SN - 0094-8276

VL - 45

SP - 8793

EP - 8802

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 17

ER -

Local Excitation of Whistler Mode Waves and Associated Langmuir Waves at Dayside Reconnection Regions

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Keywords

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