悬浮纳米碳管组合物,其制造方法,及其用途。
Compositions of suspended carbon nanotubes, methods of making the same, and USES thereof.
结果表明:纳米碳管已均匀镶嵌在镍磷晶胞上。
The result shows: the carbon nanotube homogeneous inlaid the brilliant afterbirth of Ni - P.
聚合胶受热松软,纳米碳管通过碳纤维层将其吸入。
When the glue was hot and runny, the carbon nanotubes sucked it up through the carbon-fibre layers.
利用SEM和TEM对纳米碳管的结构进行了表征。
The structure of the carbon nanotubes was represented with SEM and TEM.
纳米碳管的纯化是纳米碳管研究领域的一个重要课题。
Developing a purification technique remains a significant task in the field of carbon nanotubes research.
激光拉曼分析结果表明制得的单壁纳米碳管直径较大。
Moreover, the results of laser Raman resonant measurements indicated a larger mean diameter of our SWNTs.
本文综述了纳米碳管的几种制备方法和相关的生长机理。
In this paper, the preparation methods of carbon nanotubes and its growth mechanism are reviewed.
作者综述了纳米碳管的几种制备方法及潜在的应用前景。
The preparation methods and potential applications of carbon nanotubes are reviewed.
利用电子显微镜对纳米碳管的形貌和结构进行了观察研究。
Electron microscopes were used to examine the morphology and structure of the nanotubes.
通过乙炔气体在纳米铁颗粒上的催化热解制备了纳米碳管。
Carbon nanotubes have been produced by catalytic decomposition of acetylene on iron nanoparticles.
纳米碳管的直径仅有一米的十亿分之一长,是最理想的金属针。
Carbon nanotubes, which are just billionths of a metre across, seemed the perfect needle.
直接用纳米碳管加胶粘剂制备电极,过程很简便,但成本很高。
Use carbon nanotube as electrode material, it is easy to prepare the electrode, but it is high in price.
综述了纳米晶体材料和纳米碳管材料的力学性能研究的最新进展。
In this paper, the last research progress in the mechanical properties of nanocrystalline materials and carbon nanotubes is reviewed.
这个过程无需高温,而且用大量纳米碳管取代了单金属灯丝释放电子。
This dispenses with the heat. Also, instead of having a single metal filament release the electrons, it relies on myriad carbon nanotubes to do the same thing.
2007年,纳米碳第一次应用到肥料中,显示出明显的增产效果。
Nano Carbon was fi RST applied to fertilizer in 2007, and had an obvious effect on crops growth.
单壁纳米碳管是近年来材料科学以及凝聚态物理研究的前沿和热点。
Single walled carbon nanotube (SWNT) is a hot and frontier topic of materials science and condensed matter physics in recent years.
该发现对指导科学家合成纳米碳管和利用该矿床具有十分重要的意义。
It has very important significance for scientist to design the condition of CNTs synthesis and utilize the ore deposit.
瓦尔德博士和他的同事已经开始探索纳米碳管和聚合胶之间的相互作用。
Dr Wardle and his colleagues started exploring the interactions between carbon nanotubes and polymer glues.
纳米碳包铁粒子是在金属外面包了一层碳的粒子,可直接用于药物包埋。
Carbon-coated iron nanoparticles consist of iron encapsulated in carbon, which may be directly used for drug absorption.
发现了炭化物中存在着纳米碳管、洋葱状富勒烯结构及金刚石晶格结构。
Nanophase carbon tube, onion-like graphitic particles and diamond structure are first found in wood charcoal of Chinese Fir.
因为纳米碳管的直径仅是碳纤维直径的千分之一,它可以穿过碳纤维中的细缝。
Because these tubes are a thousandth of the diameter of carbon fibres, they can slip into the microscopic Spaces between them.
从纳米碳管的分子结构、性质以及潜在的应用,对这种新型纳米材料作了简要描述;
The molecular structures, properties and possible applications of the carbon nanotubes are introduced in this paper.
而阴离子表面活性剂以及非离子表面活性剂则不利于制备纳米碳管复合镀层的电沉积。
The results indicate that a cationic surfactant has a positive effect on the Multi-Walled Nanotube (MWNT) composite plating, while anionic and nonionic surfactant has a negative effect on it.
以镍片为基板材料,利用微波等离子体化学气相沉积法在低温条件下合成了纳米碳管膜。
Carbon nanotube films were synthesized on Ni substrate by microwave plasma chemical vapor deposition at low temperature.
研究了生长温度、气体压力、基体材料、催化剂等对有序纳米碳管阵列生长行为的影响。
Effects of temperature, pressure, catalysts and substrates on the growth of aligned carbon nanotubes are discussed.
以碳化钙和四氯化碳为碳源,反应物通过无机化学反应在密封高压釜中制备了纳米碳球。
Carbon nanospheres were synthesized by an inorganic chemical reaction with calcium carbide and chloroform as carbon sources in a sealed autoclave.
纳米碳管是一种新型的纳米材料和碳分子,其独特的分子结构和性能引起了人们的广泛关注。
As a new nanometer material and new carbon molecule, carbon nanotubes have been attracted widely attention because of its distinctive molecular structure and performance.
纳米碳管是一种新型的纳米材料和碳分子,其独特的分子结构和性能引起了人们的广泛关注。
As a new nanometer material and new carbon molecule, carbon nanotubes have been attracted widely attention because of its distinctive molecular structure and performance.
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