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Auteurs principaux: Sun, Jikai, Chang, Lei, Liu, Yu, Wang, Guojun, Kan, Zichen, Zhang, Shijie, Ma, Jingjing, Li, Dingzhou, Zhao, Yingxin
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2509.09126
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author Sun, Jikai
Chang, Lei
Liu, Yu
Wang, Guojun
Kan, Zichen
Zhang, Shijie
Ma, Jingjing
Li, Dingzhou
Zhao, Yingxin
author_facet Sun, Jikai
Chang, Lei
Liu, Yu
Wang, Guojun
Kan, Zichen
Zhang, Shijie
Ma, Jingjing
Li, Dingzhou
Zhao, Yingxin
contents During solar storms, the polar cusp often exhibits electron populations with distinct velocity distributions, which may be associated with the two-stream instability. This study reveals the evolution of the two-stream instability associated with electron velocities and the interaction between the growth phase of the two-stream instability and the electrostatic solitary waves (ESWs). The results from particle-in-cell (PIC) simulations are compared with satellite observational data and computational outcomes. The potential risks associated with two-stream instability, including surface charge accumulation and communication system interference on spacecraft, are also explored. The findings show that, in the high-latitude polar cusp region, the interaction between the solar wind plasma propagating along magnetic field lines and the upward-moving ionospheric plasma could drive two-stream instability, leading to the formation of electron hole structures in phase space and triggering a bipolar distribution of ESWs. When the spatial magnetic field and wave vector meet specific conditions, the enhanced electron cyclotron motion could suppress the formation of two-stream instability and electron hole structures, leading to a reduction in the amplitude of the ESWs. The results offer valuable insights for a deeper understanding of the impact of solar storms on the polar cusp environment, as well as for monitoring electromagnetic environment and ensuring the stable operation of spacecraft.
format Preprint
id arxiv_https___arxiv_org_abs_2509_09126
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Exploration on the Two-stream Instability in the Polar Cusp Under Solar Storm Disturbances and its Potential Impacts on Spacecraft
Sun, Jikai
Chang, Lei
Liu, Yu
Wang, Guojun
Kan, Zichen
Zhang, Shijie
Ma, Jingjing
Li, Dingzhou
Zhao, Yingxin
Plasma Physics
During solar storms, the polar cusp often exhibits electron populations with distinct velocity distributions, which may be associated with the two-stream instability. This study reveals the evolution of the two-stream instability associated with electron velocities and the interaction between the growth phase of the two-stream instability and the electrostatic solitary waves (ESWs). The results from particle-in-cell (PIC) simulations are compared with satellite observational data and computational outcomes. The potential risks associated with two-stream instability, including surface charge accumulation and communication system interference on spacecraft, are also explored. The findings show that, in the high-latitude polar cusp region, the interaction between the solar wind plasma propagating along magnetic field lines and the upward-moving ionospheric plasma could drive two-stream instability, leading to the formation of electron hole structures in phase space and triggering a bipolar distribution of ESWs. When the spatial magnetic field and wave vector meet specific conditions, the enhanced electron cyclotron motion could suppress the formation of two-stream instability and electron hole structures, leading to a reduction in the amplitude of the ESWs. The results offer valuable insights for a deeper understanding of the impact of solar storms on the polar cusp environment, as well as for monitoring electromagnetic environment and ensuring the stable operation of spacecraft.
title Exploration on the Two-stream Instability in the Polar Cusp Under Solar Storm Disturbances and its Potential Impacts on Spacecraft
topic Plasma Physics
url https://arxiv.org/abs/2509.09126