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Interactions between magnetosonic waves and radiation belt electrons: Comparisons of quasi‐linear calculations with test particle simulations
Author(s) -
Li Jinxing,
Ni Binbin,
Xie Lun,
Pu Zuyin,
Bortnik Jacob,
Thorne Richard M.,
Chen Lunjin,
Ma Qianli,
Fu Suiyan,
Zong Qiugang,
Wang Xiaogang,
Xiao Chijie,
Yao Zhonghua,
Guo Ruilong
Publication year - 2014
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1002/2014gl060461
Subject(s) - physics , electron , van allen radiation belt , computational physics , test particle , wavelength , scattering , pitch angle , radiation , wave–particle duality , magnetosphere , optics , geophysics , plasma , classical mechanics , nuclear physics , quantum mechanics
Quasi‐linear theory (QLT) has been commonly used to study the Landau resonant interaction between radiation belt electrons and magnetosonic (MS) waves. However, the long‐parallel wavelengths of MS waves can exceed their narrow spatial confinement and cause a transit‐time effect during interactions with electrons. We perform a careful investigation to validate the applicability of QLT to interactions between MS waves, which have a distribution in frequency and wave normal angle, and radiation belt electrons using test particle simulations. We show agreement between these two methods for scattering rate of intense MS waves at L = 4.5 inside the plasmapause, but find a significant inconsistency for MS waves outside the plasmapause, due to the broad transit‐time region in ( E k , α ) space. Consequently, we introduce a particle‐independent criterion to justify the validity of QLT for MS waves: the wave spatial confinement should be longer than two parallel wavelengths.