曲线呈线性关系证明电子发射确为场致发射。
Its linear F-N curve shows the electron emission was field emission.
场致发射过程中,二次电子发射现象不可忽视。
In the process of field emission, the secondary electron emission is inevitable.
将阴极与阳极板相组装,进行场致发射特性测试。
We pack the cathode panel with the anode panel and conduct the field emission experiment.
从理论和实验上研究了材料功函数对场致发射稳定性的影响。
This paper discusses experimentally and theoretically the influence of work function on the field emission stability for ta top.
该显示器件具有高的显示亮度,良好的栅控能力以及场致发射特性。
The display device possessed high displaying brightness, better grid control-ability and field emission characteristics.
利用碳纳米管作为阴极材料的场致发射显示屏是一种新型的平板器件。
The field emission panel with carbon nanotubes emitters is new flat display.
场致发射负离子及其飞行时间谱的获得导致场致发射负离子原子探针的发明。
The acquisition of field emission negative ion and its time-of-flight Spectra (TOPS) brings up to negative ion atom probe invention.
针对场致发射阵列建立了有效的三维有限元模型来分析单个尖锥的发射电流。
An effective 3-d finite element model was constructed for the field emission array to analyse the field emission current over a single tip.
利用碳纳米管薄膜作为阴极材料,给出并分析了碳纳米管薄膜阴极的场致发射特性。
With the carbon nanotube film as cathode materials, the field emission characteristics of the carbon nanotube film cathode are presented and analyzed.
当今FED研究的关键是寻找场致发射性能良好、制作工艺简单、经济可靠的阴极。
Now the key to fabricate FED device is to find a economical and credible cathode, which has excellent field emission capability and simple manufacture technology.
为此,人们采用各种类型的激光驱动光电阴极、一些热阴极和场致发射阴极作为电子源。
For this purpose, several kinds of laser-driven photocathodes, and some thermionic cathodes and field emission cathodes are applied.
场致发射显示(FED)是发光原理最接近阴极射线管(CRT)的一种平板显示器件。
Field emission display (FED) device is one of the flat panel display devices whose emission theory is the most close to the cathode-ray tube (CRT).
碳纳米管场致发射显示器是一种新型的真空器件,也是一种具有巨大应用潜力的平板型显示设备。
The field emission display with carbon nanotubes emitters is a kind of new vacuum devices, and is new flat display device with a great deal of application potential.
利用X射线衍射仪和场致发射扫描电子显微镜等手段对合成粉体的相组成、结构和形貌进行了研究。
The phase composition and microstructure of mullite powders were investigated by X-ray diffraction and field emission scanning election microscopy techniques.
随着真空纳电子学(VNE)越来越受到关注,对于场致发射显示器件(FED)的研究不断深入。
As the research of Vacuum Nanoelectronics (VNE) is attracting more attention, many progresses have taken place in the field of field emission devices (FED).
场致发射显示器是一种新型的具有竞争力的平板显示器,场致发射阴极是场致发射显示器的重要组成部分。
Field emission display is a new type of flat-panel display and field emission cathode is an important component part of field emission display.
计算了在100V门电压下不同顶端半径的场致发射电流。结果显示,场发射对顶端半径有很强的依赖性。
Field emission currents were calculated for different apex radii at the gate voltage of 100v, and the results indicated that the field emission largely depends on the apex radius.
采用钙钠平板玻璃作为封装面板,利用碳纳米管作为冷阴极材料,研制了三极结构的单色场致发射显示器件。
The carbon nanotubes were used as cold cathode materials and the soda-lime flat glass was adopted as packaging panel, so the mono-color triode FED device was developed.
以场致发射理论为基础的真空微电子器件,因其具有功耗低、电流密度大、频率高等诸多优点而倍受人们关注。
Vacuum micro-electronics devices, which are based on field emission theory, are more and more widely applied, because of their low power consumption, high current density and high frequency.
本文介绍了利用半导体硅材料制作的真空微电子器件的核心部件,场致发射硅锥阴极,的工艺研究及实验结果。
A process for the fabrication of Si cone cathode for the build up of vacuum microelectronic devices is proposed and its experimental results are given.
简要介绍场致发射与真空微电子的一般情况,尔后着重介绍应用真空微电子原理制作的场发射平板显示器(FED)。
After a brief introduction to field emission and Vacuum microelectronics, the author focuses on field emission display (FED), which is made according to principle of Vacuum microelectronics.
集束武器反对者认为此武器一旦发射将致滥杀无辜,同时那些没有引爆的小炮弹将不折不扣的把打击目标变成雷场。
Opponents of cluster munitions say they are an indiscriminate weapon when they go off; and that unexploded bomblets turn the target area into a virtual minefield.
这是和场发射能量分布测量的实验结果一致的。
This is consistent with experimental measurements on the energy distribution of emission electrons.
尤其是它具有大的长径比,低的功函数,良好的导电性和纳米级的尖端,使其能够在相对较低的电压下就能长时间地发射电子,因此被认为是一种优良的 场 致 发射阴极。
The reason, Fang says, is simple: Carbon nanotubes have a very low field-emission voltage, which means lower voltage is needed to emit the electrons that produce an image.
尤其是它具有大的长径比,低的功函数,良好的导电性和纳米级的尖端,使其能够在相对较低的电压下就能长时间地发射电子,因此被认为是一种优良的 场 致 发射阴极。
The reason, Fang says, is simple: Carbon nanotubes have a very low field-emission voltage, which means lower voltage is needed to emit the electrons that produce an image.
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