The CNTs dynamic characteristics in assemble process were studied by molecular dynamics.
本文采用分子动力学模拟系统地研究了碳纳米管在自组装过程中的运动特性.
互联网
When pH & gt ; 5, more than 99.95 % of Am can be adsorbed by CNTs.
随着硝酸浓度的降低,镅的吸附率迅速升高,当溶液的pH值大于5时, 碳纳米管对镅的吸附率达到99.95%以上.
互联网
Carbon nanotubes ( CNTs ) were prepared from acetylene at 923 K with Ni as catalysts by chemical vapor deposition ( CVD ).
以乙炔为原料气,采用Ni粉为催化剂,在923K下,由化学气相沉积法 ( CVD ) 制得了碳纳米管.
互联网
Large area well - aligned carbon nanotubes ( CNTs ) were synthesized in flames by applying an electric field.
在火焰区周围施加电磁场可稳定重复地制备出大面积形态良好的直立碳 纳米管.
互联网
The low production rate will delay the investigation and application of CNTs in many fields.
低产量极大的阻碍了碳纳米管的研究及应用.
互联网
Results show that addition of B 2 H 6 influences the growth characteristic of CNTs greatly, making CNTs bend.
结果表明:B2H6对纳米管的生长具有较大影响.
互联网
It is successful to synthesize CNTs in the fluidized - bed reactor by using the polymer ascarbon source.
结果显示使用高分子于流体化床反应器中可成功制备出奈米碳管.
互联网
CNTs are manufactured from ethylene in a reactor at an elevated temperature using a catalytic process.
碳纳米管以乙烯为原材料,在反应堆中经高温催化而成.
互联网
Thin films of carbon nanotubes ( CNTs ) were deposited on glass substrate by electrophoretic deposition ( EPD ).
利用传统的电泳方法,在 玻璃基片 上成功地制备了场发射用碳纳米管阴极薄膜.
互联网
CNTs tend to grow orderly along the axis rather than the radius in thermodynamic aspect.
热力学研究表明,碳纳米管更易于沿轴向(而不是径向)呈有序地定向生长.
互联网
By comparing the SEM and TEM images , well - aligned CNTs were grown by base growth mode.
由穿透式电子显微镜之高解析观察得知,奈米碳管非完美之管状石墨结构,而由圆锥状石墨结构所堆叠而成.
互联网
The main features of CNTs contain highly - perfect graphitization structure and high specific surface area.
兼具高石墨化程度以及高比表面积是奈米碳管的特性.
互联网
After the surface modification, CNTs was mixed with polyester powder and then been extruded and chipped.
经表面改性后, 与聚酯粉体共混造粒、挤出.
互联网
When the magnetite suspension solution was used as catalyst, crystalline bamboo - structured CNTs were obtained.
当使用磁铁矿悬浮液作为催化剂时, 得到结晶性良好之竹节状奈米碳管.
互联网
The synthesis methods and various applications of nano - hybrid CNTs materials are introduced in this article.
针对纳米碳管混成材料的主要合成方法以及其新特性,介绍了其在各方面的应用.
互联网