一种同步回旋激射不稳定性对电磁波的直接放大

本文讨论了一种同步回旋激射不稳定性对电磁波的直接放大,它基于少量在速度空间具有空心分布的中等相对论性高能电子束与本底等离子体中本征电磁模的共振相互作用。主要关心的是的参数区域(ω_e为电子等离子体频率,Ω_e为电子回旋频率)。计算表明,若电子束的单能性很高,则不稳定性增长率比同样参数下由动力效应计算得出的增长率高若干个数量级,且最大增长率处在2ω_e附近。     

托卡马克等离子体逃逸放电中的驰豫振荡与电子回旋激射不稳定性

我们研究了托卡马克等离子体进制电子引起的电子回旋激射不稳定性发生的条件，发现由反常多普勒效应及切伦科夫效应确定的准稳态速度分布又会激发电子回旋激射不稳定性，且其对本底电子回旋辐射的放大频段低于回旋频率，这与ＨＬ－１实验观察一致。     

托卡马克等离子体逃逸放电中的驰豫振荡与电子回旋激射不…

我们研究了托马克等离子体逃逸电子引起的电子回旋激射不稳定性发生的条件，发现由反常多普勒效应及切伦科夫效应确定的准稳态速度分布又会激发电子回旋激射不稳定性，且其对本底电子回旋辐射的大频段于回旋频率，这与ＨＬ－１实验观察一致。     

电子束驱动的回旋激射不稳定性进一步的数值研究

鉴于近来发现的弱相对论性电子束驱动的回旋激射(maser)不稳定性在太阳射电发射中的重 要应用，在Chen等的理论模型的基础上，对回旋激射不稳定性主要特征在更广泛的参数范围 内进行了进一步的深入研究，丰富了此类等离子体不稳定性的基本内容，而且预期在天体射 电发射机理的研究中也将得到更广泛的应用. 关键词： 回旋激射不稳定性 弱相对论性电子束 增长率     

电子回旋激射不稳定性与磁化中子星的线发射

结合典型的磁化中子星HerX-1的硬X谱线,对相对论情形的电子回旋激射不稳定性作了进一步研究。计算了FX模的频率随传播方向的变化,FX模的增长率随波矢k的变化,中子星的引力和非热电子的平均动能对不稳定性增长率的影响,并对所得结果作了分析讨论。     

电子迴旋激射不稳定性

本文分析了下述情况下的电子迴旋波的激射不稳定性:当相对性的单能高能电子斜向注入具有背景等离子体的磁场区域内,并且在电子等离子体频率与电子迴旋频率可以比拟时,考虑了背景等离子体密度远大于单能的高能电子的密度,以及与前者相反的两种情况。当单能的高能电子具有弱相对论性效应时,在电子迴旋频率的基频和二次谐波附近,分别有ο模和χ模的不稳定性存在。文中计算了这两种模的增长率,并作了讨论。 关键词：     

电子束驱动的回旋激射不稳定性

对弱相对论性电子束驱动的回旋激射(maser)不稳定性的一般理论作了详细讨论.对在获得增长率实用表达式过程中若干解析表达式的推导与细节做了仔细的补充讨论和说明，还增加了增长率的近似表达式，并由此得到了回旋激射不稳定性主要特征的解析分析以及与精确计算的比较，使整个理论有一个完整的描述.侧重解析讨论，也提供了部分一般性的数值计算结果. 关键词： 回旋激射不稳定性 弱相对论性电子束 增长率     

“A=2托卡马克堆芯等离子体基本特性研究”2006年进展

主要涉及两方面的研究内容：第一是托卡马克等离子体的磁流体气球模稳定性研究；第二是HL-2A装置电子回旋加热有关的基础理论问题。包括三方面研究成果：（1）简要报道了关于负剪切区电阻气球模不稳定性及本征函数特性，给出了增长率与等离子体参数的定标关系；（2）利用Solov’ev位形中严格的气球模方程，讨论了应用广泛的s，α平衡模型的正确性；（3）计算分析了由弱磁场侧垂直入射的电子回旋波寻常模在HL-2A等离子体中的功率沉积剖面。     

提高等离子体密度抑制逃逸电子束不稳定性的实验研究

利用ECE电子回旋辐射和Ha线辐射等托卡马克物理诊断系统,研究了Slide-away放电过程中提高等离子体密度对非麦克斯维尔分布的逃逸电子所激发的逃逸电子束不稳定性影响作用.实验结果表明:在Slide-away放电模式下,提高等离子体密度能有效抑制逃逸电子束的不稳定性.     

离子束-等离子体系统的电磁不稳定性

本文研究了离子束-等离子体系统的电磁不稳定性,考虑了离子-电子和离子-离子碰撞对维泊耳(Weibel)型电磁不稳定性增长率的影响。结果表明,在离子束-等离子体系统中可以激发维泊耳型电磁不稳定性,离子和电子之间的碰撞将使这类不稳定性的增长率增加。     

Nonlinear theory of resonant beam-plasma interaction: Nonrelativistic case

Analytic and numerical methods are used to study the nonlinear dynamics of the resonant interaction between a dense nonrelativistic electron beam and a plasma in a spatially bounded system. Regimes such as collective (Raman) and single-particle (Thomson) Cherenkov effects are considered. It is shown that in the first case, the motion of both the beam and plasma electrons exhibits significant nonlinearities. However, because of the weak coupling between the beam and the plasma, the nonlinear dynamics of the instability can be studied analytically and it can be strictly shown that saturation of instability is caused by a nonlinear shift of the radiation frequency and loss of resonance. In the second case, the nonlinear instability dynamics can only be studied numerically. In this regime, at low beam densities significant nonlinearity is only observed in the motion of the beam electrons while the plasma remains linear and saturation of the instability is caused by trapping of beam electrons in the field of the beam-excited plasma wave.     

Growth of electron energies with ion beam injection in a double plasma device

This paper reports about the observed energy growth of both high and low energetic electron species in the target plasma region with the increase in plasma potential in the source region of a double plasma device. This situation can be correlated to the injection of an ion beam from source to target plasma region. Plasma is solely produced in the source region and a low-density diffuse plasma is generated in the target region by local ionization between the neutral gas and the high energetic electrons coming from the source region. The growth of electron energy is accompanied by a decrease in diffuse plasma density. It is observed that although energy of high energetic group increases with the injected beam energy, the diffuse plasma density falls due to their decreasing population.     

Particle Simulation of Electrostatic Waves Driven by an Electron Beam

A one-dimensional electrostatic particle-in-cell simulation is performed to study electrostatic wave excitation due to an electron beam in a plasma system. The excited fundamental and harmonic waves are analyzed with the fast Fourier transformation and the wavelet transformation. The second harmonic is suggested to be generated by wave-wave coupling during the nonlinear evolution, which involves forward propagating and backward propagating Langmuir waves. Furthermore, the background electrons may be heated and accelerated by the electrostatic waves.     

Magnetic zenith effect in ionospheric modifications

The theory of ionospheric modification for the beam of powerful radio emission directed along magnetic field lines is developed. Nonlinear process of beam self-focusing on striations is shown to determine strong amplification of heating and acceleration of plasma electrons. It results in a dramatic enhancement of optic emission from the magnetic zenith region in ionospheric F-layer. An excellent agreement between the theory and recent fundamental observations at HAARP facility (Alaska) [T. Pedersen et al., Geophys. Res. Lett. (2002), in press] is demonstrated.     

Using Target Ablation for Ion Beam Quality Improvement

During the laser foil interaction,the output ion beam quality including the energy spread and beam divergence can be improved by the target ablation,due to the direct laser acceleration(DLA) electrons generated in the ablation plasma.The acceleration field established at the target rear by these electrons,which is highly directional and triangle-envelope,is helpful for the beam quality.With the help of the target ablation,both the beam divergence and energy spread will be reduced.If the ablation is more sufficient,the impact of DLA-electron-caused field will be strengthened,and the beam quality will be better,confirmed by the particle-in-cell simulation.     

Effect of the self-field of an intense relativistic electron beam on its interaction with matter

The effect of the self-field of an intense relativistic electron beam on its interaction with a dense medium was studied by solving a system of equations consisting of the kinetic equation for the fast electrons, the hydrodynamic equations for the plasma electrons, and Maxwell's equations for the electromagnetic field. It was assumed that the macroscopic parameters of the medium (its density, conductivity, and electron collision frequency) were independent of time. The system of equations was solved using high-order perturbation theory. The results show that a magnetic field is formed by the beam of fast electrons and to an equal degree by a current of thermalized electrons, which has not been taken into account before. It is shown also that the magnetic field of the beam affects its transmission through matter. In particular, the penetration depth of the electrons in matter and the transverse dimensions of the beam are both smaller than in a weak-current beam.Translated from Izvestiya Vysshykh Uchebnykh Zavedenii, Fizika, No. 10, pp. 19–24, October, 1987.The author deeply thanks K. A. Dergobuzov for support of the work, and A. V. Arzhannikov, V. A. Klimenko, and A. V. Lapp for useful discussions.     

相对论行波管慢波结构几何参数研究

 推导了无引导磁场下具有离子通道的波纹波导中的色散方程,并通过数值计算分析了该慢波结构的几何参数如波纹周期、波纹深度以及波导平均半径对相对论行波管的带宽及增益的影响,为相对论行波管的设计提供了一定的依据。     

Nonlinear theory for relativistic plasma wakefields in the blowout regime

We present a theory for nonlinear, multidimensional plasma waves with phase velocities near the speed of light. It is appropriate for describing plasma waves excited when all electrons are expelled out from a finite region by either the space charge of a short electron beam or the radiation pressure of a short intense laser. It works very well for the first bucket before phase mixing occurs. We separate the plasma response into a cavity or blowout region void of all electrons and a sheath of electrons just beyond the cavity. This simple model permits the derivation of a single equation for the boundary of the cavity. It works particularly well for narrow electron bunches and for short lasers with spot sizes matched to the radius of the cavity. It is also used to describe the structure of both the accelerating and focusing fields in the wake.