In this paper, several methods of solving the problem of electromagnetic wave propagation in a inhomogeneous plasma sheath is investigated.
本文主要研究电磁波在不均匀等离子体鞘套中传播的一些近似计算方法。
The hydrodynamic-fluid model and the self-consistent dust charging model are used to investigate the Bohm criterion for the dusty plasma sheath.
采用流体方程和自洽电荷变化模型研究了尘埃等离子体鞘层的玻姆判据。
A non power supply probe was developed to detect the plasma cloud voltage, which consists of plasma arc voltage gradient and plasma sheath voltage.
文中采用无源探针对由等离子弧梯度电压和等离子鞘层电压构成的等离子反翘(等离子云)电压进行检测。
While the reentry target passes through the earths atmosphere at ultrasonic speed, the RCS of the reentry Capsule changed violently because of the plasma sheath and wake.
当再入目标高超声速穿越大气层时,将产生等离子体鞘套和尾流,其雷达散射特性受到目标包覆等离子体参数变化的影响而产生剧烈波动。
In allusion to these problems, a plasma sheath model in an oblique magnetic field, which has one dimension coordinate space and three dimensions speed space, has been build.
针对以上问题,我们建立一个一维坐标空间三维速度空间的斜磁场作用下的等离子体鞘层物理模型。
It was shown that the ion density is higher and the electron temperature is lower in the vicinity of inductively coupled plasma sheath according to the ionic line and atomic line.
原子谱线和离子谱线特性分析表明,在鞘层附近区域感应耦合等离子体具有较高的离子密度和较低的电子温度。
In plasma, the sheath plays a crucial role in controlling the movement of the charged particles towards the electrodes (or the target).
在等离子体中,鞘层在控制带电粒子向极板(或靶材)方向运动方面起着至关重要的作用。
And corresponding the thickness of sheath of plasma and the capacitance caused by the sheath are calculated.
并相应的算出了等离子体鞘层厚度及由鞘层引起的电容。
An instability phenomenon of the current sheath implosion, namely the unstable mode, has been observed in the DPF 40 plasma focus device.
在DPF- 40等离子体焦点装置中,首次观测到径向运动电流壳层的一种不稳定现象,即不稳定模式。
On the basis of the plasma conditions in LEO. We adopt plasma thin sheath model and calculate ion collection current.
本文根据LEO中等离子体温度低、密度高、德拜长度小的特点,采用薄鞘层近似,计算了离子收集电流;
For a high plasma density and low applied voltage, the steady-state sheath thickness is more or less insensitive to variations in the spherical radius, but it is very sensitive under other conditions.
当等离子体密度较高、注入电压较低时,稳态鞘层厚度对于靶体半径的变化极不敏感。
The structure of electrostatic plasma magnetic sheath and electronegative plasma magnetic sheath are numerical simulated by fluid method.
用流体方法数值模拟了电子离子磁鞘和电负性磁鞘的结构,分析了鞘层的特性和磁场的影响。
The structure of electrostatic plasma magnetic sheath and electronegative plasma magnetic sheath are numerical simulated by fluid method.
用流体方法数值模拟了电子离子磁鞘和电负性磁鞘的结构,分析了鞘层的特性和磁场的影响。
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