光电跃迁效应是窄禁带半导体红外探测器的基本物理过程。
Optical transition effect is a fundamental physical process in the narrow gap semiconductor infrared detectors.
文章主要介绍光吸收跃迁效应在窄禁带半导体红外探测器应用方面的研究进展。
This paper reviews the research on this effect in narrow gap semiconductors for infrared photo-electronic detectors.
观测到11H、22H、33H和11L等激子跃迁结构。 计及晶格失配导致的应力效应,对子能级结构进行了理论计算。
The heavy and light hole excitonic transition structures 11H, 22H, 33H and 11L were observed and the theoretical calculations , including the strain effects, were performed.
尺寸选择激发光谱表现了较强量子尺寸效应引起的最低光学跃迁之间能量差的增大。
Size-selective photoluminescence excitation spectra reveal that energy difference between the lowest optical translations increases due to stronger size quantum effect.
跃迁的玻尔条件和光电效应的爱因斯坦定律都是微扰近似的结果,在强激光引起的跃迁中不成立。
The Bohr condition for quantum transitions and the Einstein law for photo-electric effects are approximate results of perturbation. They are violated in the transitions induced by intense lasers.
在本文中,我们研究了多光子自由-自由跃迁中原子的修饰效应。
We studied the dressed effects of atom for multiphoton Free-Free transition in this paper.
因此,发生第一激发态跃迁时,将发生分子间电子转移,从而引起荧光猝灭效应。
It suggests that intermolecular electron transfer occurs during the transition of the first excited state, which results in the fluorescence quenching effect.
从原子能级跃迁的角度,分析了低压汞灯的光子的产生过程,说明了辐射禁锢效应的概念。
The concept of radiation effects of detention was explained and photon produce process of low-pressure mercury was uras analyzed, from the perspestive of atomic energy level transition.
本文研究了具有A型跃迁结构的三能级原子与两个压缩态光场多光子相互作用过程中的一些量子效应。
Some quantum effects in the multiphoton interaction processes of a three-level A-shaped atom with two squeezed modes are studied in detail.
测定了化合物的跃迁偶极矩 ,并研究了化合物的溶致变色效应。
The transition dipole moments of two compounds were determined, the measured value being 7.
研究发现,随着量子限制效应的增强,受主跃迁能量会增加。
It is found that the transition energy of acceptors increases with the enhancement of quantum confinement.
研究发现,随着量子限制效应的增强,受主跃迁能量会增加。
It is found that the transition energy of acceptors increases with the enhancement of quantum confinement.
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