他希望在相近的转换效率下使碳纳米管的比硅材料的电池更便宜。
With carbon nanotubes, he hopes to achieve efficiency comparable to silicon solar cells for less cost.
该技术的研发团队展示了几种原子级尺寸的,采用不同的硅锗材料制成的分层结构纳米线,这种纳米线可以有效地传输电荷。
The development team demonstrated nanowires with layers of the different silicon and germanium materials that were atomically sharp and therefore more efficient at carrying electronic charges.
硅纳米线是一种新型的一维半导体光电材料。
The silicon nanometer line is one kind of late-model one thinking semiconductor photoelectricity material.
本论文通过CVD、热蒸发等方法,制备了有序化自组装纳米硅丝阵列、不同直径纳米硅丝、纳米硅管等一维纳米材料。
In this paper, we synthesized some one-dimensional nano-materials including the silicon nanowires with orderly array, different diameters and silicon nanotubes via methods of CVD,.
近年来,纳米半导体材料特别是纳米硅在光电子领域中的研究已经越来越引起人们的注意。
Recently, research on nano-semiconductor materials in photo-electronic fields has drawn more and more interest.
主要包括天然材料、改性材料的吸附,生物吸附,硅微囊技术和纳米技术等。
The new methods mainly contain the adsorption of natural materials, modification materials, humic acids, biosorption, quod of silicon micro encapsulization and nanotechnology.
对不同实验条件下所得到的多孔硅的拉曼光谱进行了分析,确认了多孔硅是具有纳米晶结构特征的材料,肯定了量子限制效应在多孔硅光致发光中的作用。
The spectra analysis showed that porous silicon is the material with nano crystal structure, and photoluminescence of PS can be explained by the model of quantum restriction effect.
本发明涉及了一种纳米硅无定型碳复合的锂离子电池负极材料及其制备方法,属于电化学电源领域。
The invention relates to a nano-silicon amorphous carbon composition lithium ion battery cathode material and a preparation method therefore, belonging to the field of electrochemistry power supply.
研究了大气状态下应用扫描隧道显微镜(STM)对金薄膜和单晶硅材料进行了纳米级电场加工实验。
The nano dots fabrication tests of Au film and single-crystal silicon were performed in air using scanning tunneling microscope(STM).
杂化材料的断面扫描电镜(SEM)分析表明, 硅氧烷的水解缩合并未形成大颗粒纳米粒子而是形成均相体系。
The Scanning electron microscopy(SEM) photographs of fracture surface of the hybrid material show that the hybrid material presents homogeneous system without obvious inorganic particle forming.
杂化材料的断面扫描电镜(SEM)分析表明, 硅氧烷的水解缩合并未形成大颗粒纳米粒子而是形成均相体系。
The Scanning electron microscopy(SEM) photographs of fracture surface of the hybrid material show that the hybrid material presents homogeneous system without obvious inorganic particle forming.
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