Nonlinear-Ion-Acoustic-Wave Instability, Threshold, Half Width of Trapped Region and Transition Region
XIAO Zuo, WANG Wen-Qing, HAO Yong-Qiang
Department of Geophysics, Peking University, Beijing 100871
Nonlinear-Ion-Acoustic-Wave Instability, Threshold, Half Width of Trapped Region and Transition Region
XIAO Zuo;WANG Wen-Qing;HAO Yong-Qiang
Department of Geophysics, Peking University, Beijing 100871
关键词 :
52.35.Pf ,
52.35.-g ,
94.20.Bb ,
94.30.Tz
Abstract : Nonlinear Landau damping of ion acoustic wave (IAW) is one of the most important phenomena in the ionosphere and in space and laboratory plasma as well. The instability growth rate of the IAW with electron drift, the amplitude threshold for exciting the nonlinear effects, the half widths of the trapped region with the trapped electrons are studied experimentally. Under the experimental conditions, it is shown that there is a frequency range of 140--160 kHz, within which the growth rate has the largest value of about 6×104 --1.5×105 s-1 . We obtain the transitional region width caused by collisions theoretically and experimentally, for the first time to our knowledge. The experimental results are in good agreement with the theoretical prediction.
Key words :
52.35.Pf
52.35.-g
94.20.Bb
94.30.Tz
出版日期: 2004-12-01
:
52.35.Pf
52.35.-g
(Waves, oscillations, and instabilities in plasmas and intense beams)
94.20.Bb
(Wave propagation)
94.30.Tz
(Electromagnetic wave propagation)
引用本文:
XIAO Zuo;WANG Wen-Qing;HAO Yong-Qiang. Nonlinear-Ion-Acoustic-Wave Instability, Threshold, Half Width of Trapped Region and Transition Region[J]. 中国物理快报, 2004, 21(12): 2461-2464.
链接本文:
https://cpl.iphy.ac.cn/CN/
或
https://cpl.iphy.ac.cn/CN/Y2004/V21/I12/2461
[1]
CHEN Lun-Jin;ZHENG Hui-Nan;XIAO Fu-Liang;WANG Shui. Effects of Spatial Variation of Thermal Electrons on Whistler-Mode Waves in Magnetosphere
[2]
YANG Lei;WU De-Jin. Effects of Charge in Heavy Ions on Solitary Kinetic Alfvén Waves in Double-Ion Plasmas
[3]
WANG Ying;GAO Zhe. Short Wavelength Ion Temperature Gradient Driven Instability in Noncircular Flux Surface Plasmas with Finite Aspect Ratio
[4]
DUAN Su-Ping;LIU Zhen-Xing;CAO Jin-Bin;SHI Jian-Kui;LU Li;LI Zhong-Yuan;Q. G. Zong;H. Reme;N. Cornilleau-Wehrlin;A. Balogh;M. Andre. Analysis of the Interaction between Low-Frequency Waves and Ions in the High-Altitude Cusp Region Observed by Satellite Cluster
[5]
WANG Chun-Hua;WANG Xiao-Gang. Effects of Dipole Moment on the Lattice Waves in One-Dimensional Dust Chain
[6]
XIAO Fu-Liang;ZHAO Hua;HE Hui-Yong. Excitation of Whistler-Mode (Chorus) Emissions during Terrestrial Substorms
[7]
GONG Ye;ZHENG Shu;XU Xiang;ZOU Xiu;LIU Jin-Yuan;LIU Yue;WANG Xiao-Gang. A Two-Flux Radiation Model for Helical Instability of Arcs
[8]
V. Babovic;M. Kovav cevic;K. Kanjevac. An Efficient Iterative Procedure for Solution of Plasma Loaded Helical Waveguide Problems
[9]
OUYANG Ji-Ting;CAO Jing;MIAO Jin-Song. Striations in Plasma Display Panel
[10]
HU You-Qiu;GUO Xiao-Cheng;LI Guo-Qiang;WANG Chi;HUANG Zhao-Hui. Oscillation of Quasi-Steady Earth’s Magnetosphere
[11]
HE Jun-Tao;ZHONG Hui-Huang;QIAN Bao-Liang;LIU Yong-Gui. A New Method for Increasing Output Power of a Three-Cavity Transit-Time Oscillator
[12]
HE Jun-Tao;ZHONG Hui-Huang;LIU Yong-Gui. A New Low-Impedance High Power Microwave Source
[13]
GAO Zhe. A New Kinetic Mode Driven by Electron Temperature Gradient
[14]
HE Kai-Fen. Hopf Bifurcation in a Nonlinear Wave System
[15]
SANG Hai-Bo;;HE Kai-Fen;. Phase Synchronization as a Mechanism of Controlling Spatiotemporal Chaos via External Periodic Signal
2004, Vol. 21 
