本文研究了半导体表面空间电荷区中的深能级中心的电场增强载流子产生效应;
The field-enhanced carrier generation of deep level centers in semiconductor space charge region has been studied.
电场增强方式的时间常数比非电场增强方式小,表明加电场有促进晶化的作用。
Raman spectra and x-ray diffraction spectra of annealed thin film showed that electrical field enhanced the MILC crystallization effect.
研究发现电场增强跟入射光斑大小,探针的锥形角,以及金属膜厚度密切相关。
The enhancement factor strongly depends on the illumination spot size, taper Angle of the probe, and the metal film thickness. The tolerance of the alignment Angle is investigated.
塔的外形增强了它的电场,在电场核心产生出闪电。
The shape of the tower enhances its electric field, which in essence, initiates the lightning.
由于静电场的场强度增强,从而与身体产生的各种相互作用也有可能增强。
As the field strength of the static field increases, so does the potential for a variety of interactions with the body.
由于栅氧化层中的固定正电荷引起正反馈的热载流子退化增强了漏端电场,使得器件特性严重退化。
A positive feedback hot-carrier degradation caused by positive fixed oxide charges increases the electrical field at the drain edge, which degrades the device characteristics seriously.
观察到由于静电场作用,瑞利散射强度显著增强。
It was observed that the Rayleigh scattering intensity increased remarkably by the action of the DC field.
说明了外加电场和磁场对太赫兹电磁辐射的产生具有增强作用。
The biased electrical field and magnetic field can enhance optically induced THz electromagnetic radiation.
电场强度的增强和适当增加水蒸气分子的密度有利于OH自由基的生成。
As a result, the number of OH radicals increases with the intensity of electric field and the density of water vapor molecules.
借助于经典电磁理论的定性分析,认为太赫兹发射光谱在外加电场、磁场作用下的增强起源于半导体中载流子的加速运动受外加电场和磁场的影响。
By the classical electromagnetic theory, the effect of applied electrical and magnetic field on THz emission can be attributed to the acceleration motion of carriers in semiconductors.
实验表明,太赫兹时域发射光谱和频谱在外加电场、磁场作用下都有增强,但是所发射的频率成分和带宽都没有改变。
The results show that THz emission spectra are enhanced by the applied electrical and magnetic field, while their frequency components and bandwidths are not changed.
随着双馈电机风电场在电网中容量比重的增大,电网导则对风电场的规范和约束也在增强。
With the increasing capacity of DFIG wind farm, the restriction of grid code to wind farm is more rigorous than ever.
随着双馈电机风电场在电网中容量比重的增大,电网导则对风电场的规范和约束也在增强。
With the increasing capacity of DFIG wind farm, the restriction of grid code to wind farm is more rigorous than ever.
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