Rapid local acceleration of relativistic radiation-belt electrons by magnetospheric chorus

Thorne, R. M.; Li, W; Ni, Binbin; Ma, Qianli; Bortnik, J.; Chen, Lunjin; Baker, D. N.; Spence, Harlan E.; Reeves, G. D.; Henderson, M. G.; Kletzing, C. A.; Kurth, W. S.; Hospodarsky, G. B.; Blake, J. B.; Fennell, J. F.; Claudepierre, S. G.; Kanekal, S. G.

doi:10.1038/nature12889

Cited by 635 publications

(909 citation statements)

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“…This is a fundamental process, responsible for many phenomena in space and laboratory plasmas. One of the brightest examples is electron acceleration in radiation belts, which results in aurora formation [1,2] and represents a real hazard for artificial satellites in activity [3]. Assuming that the wave spectrum is wide enough and the wave intensity is sufficiently low, one can model the wave-particle resonant interactions using quasi-linear theory [4][5][6][7] generalized for systems with inhomogeneous magnetic field and background plasma [8,9].…”

Section: Introductionmentioning

confidence: 99%

Probabilistic approach to nonlinear wave-particle resonant interaction

et al. 2017

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Citation: ARTEMYEV, A.V. ...et al., 2017. Probabilistic approach to nonlinear wave-particle resonant interaction. Physical Review E, 95:023204.Additional Information:• This paper was accepted for publication in the journal Physi- Probabilistic approach to nonlinear wave-particle resonant interaction In this paper we provide a theoretical model describing the evolution of the charged particle distribution function in a system with nonlinear wave particle interactions. Considering a system with strong electrostatic waves propagating in an inhomogeneous magnetic field, we demonstrate that individual particle motion can be characterized by the probability of trapping into the resonance with the wave and by the efficiency of scattering at resonance. These characteristics, being derived for a particular plasma system, can be used to construct a kinetic equation (or generalized FokkerPlanck equation) modelling the long-term evolution of the particle distribution. In this equation, effects of charged particle trapping and transport in phase space are simulated with a nonlocal operator. We demonstrate that solutions of the derived kinetic equations agree with results of test particle tracing. The applicability of the proposed approach for the description of space and laboratory plasma systems is also discussed.

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Section: Introductionmentioning

confidence: 99%

Probabilistic approach to nonlinear wave-particle resonant interaction

et al. 2017

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“…[1][2][3][4][5] These waves are believed to be a dominant source of "killer electrons" (∼MeV) in Earth's magnetosphere, 3,5,6 which is a major threat to astronauts and operating satellites. Furthermore, they are also the primary contributor of strong diffuse auroral precipitation into the Earth's atmosphere, 2,7 resulting in enhanced chemical changes of the atmosphere.…”

Section: Introductionmentioning

confidence: 99%

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

Gao

Wang

et al. 2018

AIP Advances

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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.

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“…37,40,42,58,64,67 Multiple spacecraft observations of intense emissions of parallel (relative to the background magnetic field) whistler-mode waves during geomagnetic storms and substorms 1,33,38 have led to the suggestion that these parallel waves could be responsible for almost all the recorded variations of electron fluxes. In addition, oblique wave damping due to Landau resonance with a dense population of suprathermal electrons 20,36 often sensibly decreases the amplitudes of oblique whistler-mode waves along their propagation.…”

Section: Introductionmentioning

confidence: 99%

Probability of relativistic electron trapping by parallel and oblique whistler-mode waves in Earth's radiation belts

et al. 2015

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International audienceWe investigate electron trapping by high-amplitude whistler-mode waves propagating at small as well as large angles relative to geomagnetic field lines. The inhomogeneity of the background magnetic field can result in an effective acceleration of trapped particles. Here, we derive useful analytical expressions for the probability of electron trapping by both parallel and oblique waves, paving the way for a full analytical description of trapping effects on the particle distribution. Numerical integrations of particle trajectories allow to demonstrate the accuracy of the derived analytical estimates. For realistic wave amplitudes, the levels of probabilities of trapping are generally comparable for oblique and parallel waves, but they turn out to be most efficient over complementary energy ranges. Trapping acceleration of <100 keV electrons is mainly provided by oblique waves, while parallel waves are responsible for the trapping acceleration of >100 keV electrons. (C) 2015 AIP Publishing LLC

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Rapid local acceleration of relativistic radiation-belt electrons by magnetospheric chorus

Cited by 635 publications

References 25 publications

Probabilistic approach to nonlinear wave-particle resonant interaction

Probabilistic approach to nonlinear wave-particle resonant interaction

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

Probability of relativistic electron trapping by parallel and oblique whistler-mode waves in Earth's radiation belts

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