乙醇催化燃烧法可以方便的制备出碳纳米管和碳纳米纤维。
The ethanol catalytic combustion technique was used to synthesize carbon nanotubes and carbon nanofibers.
低密度导电材料可以包括任选与碳纳米纤维结合的金属丝网。
Low density conductive materials can include metal screens, optionally in combination with carbon nanofibers.
本文利用分子模拟的方法模拟了氢气分子在平板状碳纳米纤维中的吸附。
Hydrogen adsorption in carbon nanofibres termed platelet has been simulated with molecule simulation method in the paper.
对甲烷催化裂解制氢和生产碳纳米纤维两个过程耦合的可能性进行了研究。
The feasibility of simultaneous hydrogen and carbon nanofibers production from the catalytic decomposition of methane was discussed.
介绍了一种既简单又经济的用于制备Y形结构碳纳米纤维的催化燃烧方法。
A simple and economical method for synthesizing Y-like carbon nanofibers was introduced.
通过化学气相反应,碳纳米管被组装到碳化的电纺纳米纤维上,形成多刺的碳纳米纤维结构。
Via chemical vapor reaction, carbon nanotubes were assembled on the surface of carbonized electrospun nanofibers to form hairy carbon nanofiber structure.
本文利用介孔碳的软模板合成方法和阳极氧化铝膜的孔道限域性制备有序的介孔碳纳米纤维。
Ordered mesoporous carbon nanofibers were prepared by combining the soft template synthesis method of mesoporous carbons with the confinement of channels of anode alumina membranes.
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.
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.
综述聚合物基复合材料中碳纳米管传感的最新进展:碳纳米管与树脂共混、碳纳米管涂层纤维、碳纳米线和碳纳米纸。
Research advances in carbon nanotubes sensing in polymer composites are reviewed: carbon nanotubes filler, carbon nanotubes coated fiber, carbon nanotubes yarn and carbon nanotubes paper.
结果表明:缩短停留时间和高温处理使得构成纳米炭纤维催化生成的炭含量增加,碳层的结构接近石墨晶体的有序结构。
The result indicates that shortening of reaction time and graphitic treatment make catalytic carbon increasing and carbon layer incline to the order structure of graphitic crystalline.
细川护熙美光科技公司开发的碳纳米颗粒拥有卓越的耐热性。它均匀的分布在芳纶纤维上,同时制定出纳米颗粒的生产条件。
Hosokawa Micron developed nanoparticles with superior heat resistance that can be uniformly dispersed in aramid fiber, and also established conditions for manufacturing the nanoparticles.
细川护熙美光科技公司开发的碳纳米颗粒拥有卓越的耐热性。它均匀的分布在芳纶纤维上,同时制定出纳米颗粒的生产条件。
Hosokawa Micron developed nanoparticles with superior heat resistance that can be uniformly dispersed in aramid fiber, and also established conditions for manufacturing the nanoparticles.
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