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Gap Formation Around 0.5Ω<sub><i>e</i></sub> in the Whistler‐Mode Waves Due To the Plateau‐Like Shape in the Parallel Electron Distribution: 2D PIC Simulations

Huayue Chen, Xinliang Gao, Quanming Lu, Kai Fan, Yangguang Ke, Xueyi Wang, Shui Wang

2022Journal of Geophysical Research Space Physics16 citationsDOI

Abstract

Abstract The power gap around 0.5Ω e (where Ω e is the equatorial electron gyrofrequency) of whistler‐mode waves is commonly observed in the Earth's inner magnetosphere, but its generation mechanism is still under debate. By performing two‐dimensional particle‐in‐cell simulations in a uniform background magnetic field, we investigate the spectral properties of whistler‐mode waves excited by temperature anisotropic electrons. The waves have positive growth rates in a wide range of normal angles ( θ ≈ 0°–35°), resulting in the generation of both parallel and nonparallel waves. Although the nonparallel wave modes are weaker than the parallel ones, they can cause the plateau‐like shape around 0.5 V Ae (where V Ae represent the electron Alfven speed) in the parallel direction of electron velocity distribution. The plateau‐like electron component can then lead to severe damping in the waves around 0.5Ω e via the cyclotron resonance, and the power gap is formed. This mechanism is called as “spectrum bite”. Our study sheds fresh light on the well‐known gap formation at ∼0.5Ω e in the whistler‐mode waves, which is ubiquitously detected near the equator in the inner magnetosphere.

Topics & Concepts

WhistlerPhysicsMagnetosphereElectronComputational physicsExcited stateMagnetic fieldAtomic physicsQuantum mechanicsIonosphere and magnetosphere dynamicsEarthquake Detection and AnalysisGeomagnetism and Paleomagnetism Studies