We report recent experimental evidence for the quantum confinement effect in 3C-SiC nanoparticles.
本文报道了非晶氨化硅纳米粒子的制备及量子限制效应。
Due to quantum confinement effect, band gap of semiconductor nanocrystals (NCs) is dependent on the particle size.
由于量子限域效应,半导体纳米晶的能带宽随粒子大小而改变。
The optical direct bandgap taking blue shift can be explain by quantum confinement effect effective mass approximate method.
针对其光学直接禁带宽度发生蓝移,使用量子限域和有效质量近似方法得到了解释。
Most of theoretical researches studied the quantum confinement effect on the luminescence of porous Si and Si nanocrystallites.
大部分理论计算研究的是量子限制对多孔硅和纳米硅晶发光的效应。
Secondly, phonon transport in thermoelectric materials will be discussed, where strong interface scattering and quantum confinement effect have been observed.
其次,对热电材料的声子输运问题进行研究,观察到了强的界面散射和量子限制效应。
The UV-visible absorption and photoluminescence spectra show the quantum confinement effect clearly. The time-resolved photoluminescence spectra have also been examined.
紫外可见吸收光谱和光致发光荧光光谱清楚的显示出量子限域效应,同时也研究了量子点的时间分辨荧光光谱。
This experimental finding is in good agreement with the result of calculation of electronic structure. The evidence strongly supports the model of quantum confinement effect.
这一发现恰与理论计算结果一致,从实验上支持了多孔硅的量子限域模型。
Semiconductor nanocrystals have unique optical and electrical properties, due to quantum size effect and dielectric confinement effect.
半导体纳米晶由于量子尺寸效应和介电限域效应使它们具有独特的光致发光性能。
Semiconductor nanocrystals have unique optical and electrical properties, due to quantum size effect and dielectric confinement effect.
半导体纳米晶由于量子尺寸效应和介电限域效应使它们具有独特的光致发光性能。
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