未经处理的碳纳米管常呈现团聚形态。
The raw material of carbon nanotubes always agglomerates severely.
细微的碳纳米管在肺部可能会带来类似的威胁。
The action of microscopic nanotubes in the lungs holds similar risks.
所用的碳纳米管是用热灯丝化学气相沉积法合成的。
Carbon nanotubes in experiments were synthesized by hot filament chemical vapor deposition.
通过物理方式,构造出高度可溶的碳纳米管混合物。
Through physical mixing, highly soluble CNTs hybrids were fabricated.
这种未来的设备会植入一个包含微小铁晶体的碳纳米管。
The proposed device would place a microscopic iron crystal inside a carbon nanotube.
这种微小的,多才多艺的碳纳米管可以一次运输一个单分子
The tiny, multitalented carbon tubes can carry single molecules, one at a time.
研究所用的碳纳米管是用热灯丝化学气相沉积法合成的。
The carbon nanotubes were synthesized by the heat filament chemical vapor deposition.
扫描电镜图显示该圆片由局部规则排列的碳纳米管构成;
Scanning electron microscope pictures showed that the pellet consisted of highly aligned nanotubes.
纳米聚团床催化裂解法制得的碳纳米管均以团聚体形式存在。
Carbon nanotubes (CNTs) manufactured in a nano agglomerated fluidized bed by catalytic decomposition method usually group into agglomerates.
制备的碳纳米管的原子排列是一种短程有序排列,是非晶态结构。
The carbon tubes prepared were in short range order with amorphous structure.
人们已在能够胜任的材料方面取得一些进展,像是特别研制的碳纳米管。
There has been some progress with materials that can do this, including specially engineered carbon nanotubes.
实验证实浓度为2 5%的碳纳米管浆料制得的阴极有最佳的阵列密度。
The test result proves that the CNT cathode with optimum array density is fabricated by the CNT paste with a density of 2.5 %.
前阵子荷兰科学家成功创造出依靠单个电子进行开关的碳纳米管晶体管。
A while back Dutch scientists managed to create a nanotube activated transistor that could toggle on and off with the flow of a single electron.
实验证实浓度为2.5%的碳纳米管浆料制得的阴极有最佳的阵列密度。
The test result proves that the CNT cathode. With optimum array density was fabricated by the CNT paste with a density of 2.5%.
这里的碳纳米管基本上就是一层卷成筒的石墨,其大小相当于一个dna分子。
In this case, a carbon nanotube is basically a rolled up sheet of graphene the size of a DNA molecule.
提纯后的碳纳米管的纯度较高,而且分散性较好,为其后期应用奠定了基础。
After the process above, the purity of carbon nanotubes is high, and their dispersivity is good, which establishes the foundation for its employing in later stage.
此类聚合物衍生的碳纳米管具有相对较好的亲水性表面,可“溶解”在溶剂中。
The polymer derivatized carbon nanotubes can dissolve in some solvents depending on their good hydrophilic surface.
采用气凝胶与干凝胶两种催化剂载体通过化学气相淀积方法制备出螺旋状的碳纳米管。
Helical carbon nanotubes were synthesized by a chemical vapour deposition method from both silica aerogels and silica xerogels containing catalysts.
为实现碳纳米管在聚合物中的分散,首先要求加入的碳纳米管本身具备足够的分散度。
To achieve sufficient dispersion of carbon nanotubes in polymer matrixes, raw carbon nanotubes must be with enough dispersivity initially.
采用场发射扫描电镜分析了复合镀层的表面和初始界面上的碳纳米管存在形式和分布。
Scanning electron microscope was used to observe the conformation and distribution of carbon nanotubes on the initial interface of coatings.
在忽略其他条件影响下,长径比相同的碳纳米管,电荷密度相对分布曲线趋势完全相同。
Without considering other aspects carbon nanotubes with the same aspect ratio have entirely uniform trend in charge density relative distribution curve.
各种不同方法制备的碳纳米管样品,大部分含有无定形炭,碳纳米颗粒和催化剂等杂质。
Carbon nanotubes (CNTs) samples have been synthesized by many different method. They almost have impurities, such as amorphous, carbon nanoparticles and catalyst particles.
这是麻省理工学院的化学工程师团队第一次观察到单离子通过一个微小的碳纳米管渠道进行运输。
For the first time, a team of MIT chemical engineers has observed single ions marching through a tiny carbon-nanotube channel.
用自组装技术组装的碳纳米管具有新奇的光、电、催化等功能和特性,因此具有良好的发展前景。
Self-assembled carbon nanotubes have a promising future due to their fancy optical, electronic, catalytic functions and properties.
在天然石墨(NG)中掺杂不同比例的碳纳米管(CNT)得到纳米碳与石墨碳的复合材料。
When natural graphite(NG) is doped with different ratios of carbon nanotube(CNT), a composite material formed by nano-C and graphite-C was obtained.
有效分离后的碳纳米管具有相似的电学、力学和光学性能,因而使碳纳米管具有更大的潜在应用价值。
After effective separation, carbon nanotubes have similar properties, such as electricity, mechanics and optics, so they will have greater potential application.
Strano博士在《应用化学》杂志上表述了自己的发明的核心,这个核心是一排加工过的碳纳米管。
The core of Dr Strano's invention, which he describes in Angewandte Chemie, is an array of treated carbon nanotubes.
相比于以往的碳纳米管纯化或修饰工艺,微波辅助加热具’有操作简单,用时短,低能耗等明显优势。
The technique exhibited obvious advantages over those methods mentioned above, including simple handle, low energy consumption and quick rate.
结果表明,采用真空热压后热轧工艺制备的碳纳米管铜基复合材料的致密度较高且能有效地防止被氧化。
SEM and XRD results show that the composite that is hot rolled after vacuum forming, has relatively high density and can avoid being oxidized effectively.
结果表明,采用真空热压后热轧工艺制备的碳纳米管铜基复合材料的致密度较高且能有效地防止被氧化。
SEM and XRD results show that the composite that is hot rolled after vacuum forming, has relatively high density and can avoid being oxidized effectively.
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