Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere

Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere

Whistler-mode waves play a crucial role in controlling electron dynamics in the Earth’s Van Allen radiation belt, which is increasingly important for spacecraft safety. Using THEMIS waveform data, Gao et al. [X. L. Gao, Q. Lu, J. Bortnik, W. Li, L. Chen, and S. Wang, Geophys. Res. Lett., 43, 2343-23...

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Main Authors: Xinliang Gao, Quanming Lu, Shaojie Wang, Shui Wang
Format: Article
Language:English
Published: AIP Publishing LLC 2018-05-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/1.5025507
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spelling doaj-2b22cec220ae49d08acd301a138224202020-11-24T22:02:59ZengAIP Publishing LLCAIP Advances2158-32262018-05-0185055003055003-810.1063/1.5025507009805ADVTheoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphereXinliang Gao0Quanming Lu1Shaojie Wang2Shui Wang3CAS Key Laboratory of Geospace Environment, Department of Geophysics and Planetary Science, University of Science and Technology of China, Hefei 230026, ChinaCAS Key Laboratory of Geospace Environment, Department of Geophysics and Planetary Science, University of Science and Technology of China, Hefei 230026, ChinaCAS Key Laboratory of Geospace Environment, Department of Geophysics and Planetary Science, University of Science and Technology of China, Hefei 230026, ChinaCAS Key Laboratory of Geospace Environment, Department of Geophysics and Planetary Science, University of Science and Technology of China, Hefei 230026, ChinaWhistler-mode waves play a crucial role in controlling electron dynamics in the Earth’s Van Allen radiation belt, which is increasingly important for spacecraft safety. Using THEMIS waveform data, Gao et al. [X. L. Gao, Q. Lu, J. Bortnik, W. Li, L. Chen, and S. Wang, Geophys. Res. Lett., 43, 2343-2350, 2016] have reported two multiband chorus events, wherein upper-band chorus appears at harmonics of lower-band chorus. They proposed that upper-band harmonic waves are excited through the nonlinear coupling between the electromagnetic and electrostatic components of lower-band chorus, a second-order effect called “lower band cascade”. However, the theoretical explanation of lower band cascade was not thoroughly explained in the earlier work. In this paper, based on a cold plasma assumption, we have obtained the explicit nonlinear driven force of lower band cascade through a full nonlinear theoretical analysis, which includes both the ponderomotive force and coupling between electrostatic and electromagnetic components of the pump whistler wave. Moreover, we discover the existence of an efficient energy-transfer (E-t) channel from lower-band to upper-band whistler-mode waves during lower band cascade for the first time, which is also confirmed by PIC simulations. For lower-band whistler-mode waves with a small wave normal angle (WNA), the E-t channel is detected when the driven upper-band wave nearly satisfies the linear dispersion relation of whistler mode. While, for lower-band waves with a large WNA, the E-t channel is found when the lower-band wave is close to its resonant frequency, and the driven upper-band wave becomes quasi-electrostatic. Through this efficient channel, the harmonic upper band of whistler waves is generated through energy cascade from the lower band, and the two-band spectral structure of whistler waves is then formed. Both two types of banded whistler-mode spectrum have also been successfully reproduced by PIC simulations.http://dx.doi.org/10.1063/1.5025507
collection DOAJ
language English
format Article
sources DOAJ
author Xinliang Gao
Quanming Lu
Shaojie Wang
Shui Wang
spellingShingle Xinliang Gao
Quanming Lu
Shaojie Wang
Shui Wang
Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere
AIP Advances
author_facet Xinliang Gao
Quanming Lu
Shaojie Wang
Shui Wang
author_sort Xinliang Gao
title Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere
title_short Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere
title_full Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere
title_fullStr Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere
title_full_unstemmed Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth’s magnetosphere
title_sort theoretical analysis on lower band cascade as a mechanism for multiband chorus in the earth’s magnetosphere
publisher AIP Publishing LLC
series AIP Advances
issn 2158-3226
publishDate 2018-05-01
description Whistler-mode waves play a crucial role in controlling electron dynamics in the Earth’s Van Allen radiation belt, which is increasingly important for spacecraft safety. Using THEMIS waveform data, Gao et al. [X. L. Gao, Q. Lu, J. Bortnik, W. Li, L. Chen, and S. Wang, Geophys. Res. Lett., 43, 2343-2350, 2016] have reported two multiband chorus events, wherein upper-band chorus appears at harmonics of lower-band chorus. They proposed that upper-band harmonic waves are excited through the nonlinear coupling between the electromagnetic and electrostatic components of lower-band chorus, a second-order effect called “lower band cascade”. However, the theoretical explanation of lower band cascade was not thoroughly explained in the earlier work. In this paper, based on a cold plasma assumption, we have obtained the explicit nonlinear driven force of lower band cascade through a full nonlinear theoretical analysis, which includes both the ponderomotive force and coupling between electrostatic and electromagnetic components of the pump whistler wave. Moreover, we discover the existence of an efficient energy-transfer (E-t) channel from lower-band to upper-band whistler-mode waves during lower band cascade for the first time, which is also confirmed by PIC simulations. For lower-band whistler-mode waves with a small wave normal angle (WNA), the E-t channel is detected when the driven upper-band wave nearly satisfies the linear dispersion relation of whistler mode. While, for lower-band waves with a large WNA, the E-t channel is found when the lower-band wave is close to its resonant frequency, and the driven upper-band wave becomes quasi-electrostatic. Through this efficient channel, the harmonic upper band of whistler waves is generated through energy cascade from the lower band, and the two-band spectral structure of whistler waves is then formed. Both two types of banded whistler-mode spectrum have also been successfully reproduced by PIC simulations.
url http://dx.doi.org/10.1063/1.5025507
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AT quanminglu theoreticalanalysisonlowerbandcascadeasamechanismformultibandchorusintheearthsmagnetosphere
AT shaojiewang theoreticalanalysisonlowerbandcascadeasamechanismformultibandchorusintheearthsmagnetosphere
AT shuiwang theoreticalanalysisonlowerbandcascadeasamechanismformultibandchorusintheearthsmagnetosphere
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