基于HRTEM和Raman分析定向多壁碳纳米管阵列的生长机理

以二茂铁、二甲苯为前驱体,石英为衬底,在850 oC的管式炉内采用化学气相沉积法制备出了定向碳纳米管阵列. 高分辨透射电子显微镜和拉曼光谱的结果表明：碳纳米管阵列具有良好的定向性和多壁管状结构,石墨化程度高,并且只在表面存在少量单壁碳纳米管.定向多壁碳纳米管阵列的生长模式为“底部”生长模式,即在生长的初期,当催化剂颗粒较小时,析出的碳原子生成了单壁碳纳米管或与其性质类似的多壁碳纳米管(一般层数小于5层);催化剂颗粒逐渐长大后,大量的碳原子析出后生成了普通的多壁碳纳米管,从而形成了单壁碳纳米管只存在于碳纳米管阵列膜表面和多层碳纳米管膜表面与界面的现象.     

大电流密度碳纳米管场致发射阴极阵列的研制

 设计了一种由TiN，Al，Fe和牺牲层构成的堆栈式催化剂层结构，采用微波等离子体化学气相沉积法实现碳纳米管阵列高速笔直生长。SEM和TEM结果表明，生长出来的碳纳米管为典型的多壁碳纳米管，长度和直径均匀，排列整齐并垂直于基底，生长速率大于5 μm/min，晶格缺陷少。场致发射测试结果表明：碳纳米管的发射阵列具有良好的电流发射稳定性，最大电流密度大于6 A/cm2。紫外光电子能谱法（UPS）测试出碳纳米管的功函数为4.59 eV，则相应的场致发射陈列的场增强因子大于1 400。     

碳纳米管的生长机理、可控生长及应用探索

碳纳米管的可控制生长,及其宏观尺度结构的制备,对于碳纳米管的应用具有重要的意义,为了实现准确的生长控制,对碳纳米管生长机理的深入了解是不可缺少的前提条件.文章介绍了我们近年来在碳纳米管生长机理、可控生长及其应用方面的一些进展.通过引入^13C标记法,我们证实了化学气相沉积法中碳纳米管以析出模式生长;实时改变生长的气相成份和流量,可以在碳纳米管阵列上留下标记序列,并据此测量出其生长速率及活化能.将超顺排碳纳米管阵列的合成扩展到4英寸规模,并发展了用挥发性有机溶剂处理碳纳米管线的方法,大大提高了其强度和可操作性.处理后的碳纳米管线可以方便地用于热电子源、高电流密度冷阴极以及荧光灯等.热界面材料在IT产业中具有重要的应用背景,我们用碳纳米管阵列制备的复合材料具有极高的热导率和极低的界面热阻,同时发展了化学修饰、端部剪裁、金属集热层等新技术以制备高性能的碳纳米管热界面材料.     

多层纳米碳管膜的大面积可控制生长

文章介绍了利用化学气相沉积法在Si和石英基片上大面积生长多层碳纳米管膜的研究成果,通过调节生长参数,不仅可以获得高度取向的碳纳米纤维,还可获得不同直径,不同图案的高度取向的碳纳米管膜,取向碳纳米管膜的可控制制备,为研究碳纳米管的物理,化学性能,特别是为碳纳米管场发射平面图像显示器的应用研究,奠定了坚实的基础。     

离子轰击控制准直碳纳米管生长的研究

用CH₄,H₂和NH₃作为反应气体，利用等离子体增强热丝化学汽相沉积制备出准直碳纳米管，并用扫描电子显微镜研究了不同负偏压对准直碳纳米管生长的影响. 结果表明，随着负偏压的增大，准直碳纳米管的平均直径减小、平均长度增大. 由于辉光放电的产生，在衬底表面附近形成阴极鞘层，并在阴极鞘层内形成大量的离子和在衬底表面附近形成很强的电场. 离子在电场的作用下对衬底表面的强烈轰击将对准直碳纳米管的生长产生影响. 结合有关理论，分析和讨论了离子的轰击对准 关键词： 准直碳纳米管 离子轰击 负偏压     

碳纳米管微悬臂梁红外探测器的优化设计

对复合层微悬臂梁红外探测器进行了理论分析，并建立了相应的理论模型，实验研究了在硅基底上生长碳纳米管的吸热特性，优化设计了一种生长有碳纳米管的三层硅微悬臂梁谐振式红外探测器。该探测器基于复合层微悬臂梁的谐振频率随着微悬臂梁温度的改变发生漂移的特性，在一定的红外辐射下，微悬臂梁的温度会随着辐射光强的强弱而发生变化，从而根据微悬臂梁谐振频率的漂移而感知温度变化实现对辐射光的探测，利用碳纳米管的红外吸收特性，在二层微悬臂梁上生长碳纳米管薄膜作为吸收层，提高了微悬臂梁探测器的红外吸收性能。研究表明：其功率灵敏度可达fw级，比传统的静态测试方法提高了两个数量级。而且这种基于微机电系统技术的传感器与集成电路工艺是兼容的。     

碳纳米管/聚苯胺纳米复合管的制备及其微波介电特性研究

用原位乳液聚合法在碳纳米管表面包覆聚苯胺，制备出了碳纳米管/聚苯胺一维纳米复合管.复合管的直径为50—80 nm，聚苯胺包覆层的厚度为20—30 nm，聚苯胺在碳纳米管表面以层状和枝晶状两种形态生长.研究了碳纳米管/聚苯胺复合管在2—18 GHz的微波介电特性.与纯碳纳米管相比，碳纳米管/聚苯胺复合管的介电常数的实部ε′和虚部ε″在2—18 GHz随频率变化较小，在低频波段介电常数值较小，作为微波吸收剂容易实现与自由空间的阻抗匹配，而且它的介电损耗角正切(tanδ=ε″/ε′)较高，是一种很好的微波吸收剂. 关键词： 碳纳米管 聚苯胺 微波介电特性 微波吸收剂     

快速生长超长定向碳纳米管阵列的制备及机理

 采用一种无模板的化学气相沉积法裂解金属有机物,以二茂铁为催化剂,二甲苯为碳源,利用单温炉加热装置在100 min内成功制备了2.7 mm超长定向碳纳米管阵列,生长速率高达27 μm·min^-1。运用扫描电子显微镜、透射电子显微镜、拉曼光谱对定向碳纳米管阵列进行形貌观察和表征,结果表明:制得的碳纳米管阵列具有优越的定向性和管结构,并且石墨化程度高。给出了快速生长超长定向碳纳米管阵列的优化制备条件,结合表征结果讨论了碳纳米管阵列的生长机制,认为超长碳纳米管阵列采用的是一种催化剂固定不动的开口生长方式,碳源和催化剂的连续供应保证了超长碳纳米管阵列的快速生长。     

一些新颖碳纳米结构的高分辨率透射电子显微镜研究

在双阳极电弧放电的阴极沉积物中已发现扁平碳纳米壳、碳纳米棒和棒-管相连的碳纳米结构.高分辨率透射电子显微镜(HRTEM)确认了碳纳米管直接生长在纳米棒之上,因而碳纳米管生长开端的来龙去脉清晰可见.另外,HRTEM图像显示,多壳层碳纳米棒有一条中心线.有可能这是一种基于单键和三重键交替“sp”杂化的炔链碳同素异形体. 关键词：     

LPCVD法制备碳纳米管薄膜及其场发射性能的研究

采用低压化学气相沉积法(LPCVD)在镍片上直接制备碳纳米管(CNTs)薄膜,系统地研究了生长温度(500~800℃)对碳纳米管薄膜形貌、结构及场发射性能的影响,并对此方法的生长机理进行了分析。当温度从500℃升高到650℃时,碳纳米管的生长速率随着温度升高而增大,而温度继续上升,速率则明显减小。利用扫描电镜(SEM)和拉曼光谱仪表征和检测了碳纳米管薄膜的形貌和结构。碳纳米管的管径、长度、一致性和晶化程度随温度都有明显的变化。同时还对碳纳米管薄膜的场发射特性进行了测试,对其场发射机理进行了深入地探讨,表明温度对碳纳米管的性能有很大影响,并存在最优化的温度条件。实验结果表明碳纳米管薄膜的形貌、结构及其场发射性能可通过生长温度进行一定范围的控制。     

碳纳米管在银基底上的表面增强拉曼散射光谱研究(英文)

介绍了一种单壁碳纳米管表面增强拉曼散射的新方法。依据碳纳米管独特的力学性能,在银表面直接研磨单壁碳纳米管,在形成纳米级粗糙银表面的同时,单壁碳纳米管也吸附在银表面上。在银表面粗糙程度和单壁碳纳米管厚度适中的区域得到了高质量的单壁碳纳米管SERS谱。该方法消除了溶剂的干扰,保证了结果的准确性,理论分析和实验结果表明该方法是正确的、可行的     

A continuous synthesis of carbon nanotubes by dc thermal plasma jet

In this contribution we present a dc thermal plasma jet route for the continuous synthesis of single- and multi- walled carbon nanotubes. Our findings show the as produced product to be dependent on the plasma atmosphere and catalyst. Multi walled carbon nanotubes can be synthesized without a catalyst. Single walled carbon nanotubes require the presence of a catalyst (Ni-Ce) and the addition of hydrogen to the buffer gas. Increasing the amount of hydrogen added to the reaction significantly improves the nanotube yield. PACS 81.07.De; 36.40.Gk; 63.50.+x; 68.37.Lp; 68.37.Hk     

拉曼描述碳纳米管系统:缺陷探测,产物热处理,过程分析和催化剂(英文)

利用拉曼散射技术从多角度研究了碳纳米管合成系统。发现拉曼散射技术不仅可表征碳纳米材料本身的特性,而且可分析宏观的多壁碳纳米管与单壁碳纳米管的生长过程。针对不同的碳纳米材料的生长特性提出了催化剂与反应器设计及过程控制的研究方向。同时还发展了一种基于拉曼光谱法的定量测定单壁碳纳米管含量的方法。     

Effects of initial compression stress on wave propagation in carbon nanotubes

An analytical method to investigate wave propagation in single- and double- walled carbon nanotubes under initial compression stress is presented. The nanotube structures are treated within the multilayer thin shell approximation with the elastic properties taken to be those of the graphene sheet. The governing equations are derived based on Flügge equations of motion. Frequency equations of wave propagation in single and double wall carbon nanotubes are described through the effects of initial compression stress and van der Waals force. To show the effects of Initial compression stress on the wave propagation in nanotubes, the symmetrical mode can be analyzed based on the present elastic continuum model. It is shown that the wave speed are sensitive to the compression stress especially for the lower frequencies.     

Wave propagation in double walled carbon nanotubes by using doublet mechanics theory

Flexural and axial wave propagation in double walled carbon nanotubes embedded in an elastic medium and axial wave propagation in single walled carbon nanotubes are investigated. A length scale dependent theory which is called doublet mechanics is used in the analysis. Governing equations are obtained by using Hamilton principle. Doublet mechanics results are compared with classical elasticity and other size dependent continuum theories such as strain gradient theory, nonlocal theory and lattice dynamics. In addition, experimental wave frequencies of graphite are compared with the doublet mechanics theory. It is obtained that doublet mechanics gives accurate results for flexural and axial wave propagation in nanotubes. Thus, doublet mechanics can be used for the design of electro-mechanical nano-devices such as nanomotors, nanosensors and oscillators.     

Micromechanical properties of poly(butylene terephthalate) nanocomposites with single- and multi-walled carbon nanotubes

Polymer nanocomposites with carbon nanotubes (CNT) are becoming important structural materials because of their superior mechanical properties and easy processability. The objective of the work is to investigate the influence of small amounts of single walled carbon nanotubes (SWCNT), as well as multi-walled carbon nanotubes (MWCNT), on the microhardness of a thermoplastic polymer such as poly(butylene terephthalate) (PBT). The nanocomposites were obtained by introducing the CNT into the reaction mixture during the synthesis of PBT. The polymers without carbon nanotubes (reference material) and with carbon nanotubes were synthesized using an in-situ polycondensation reaction process. Weight percentages ranging from 0.01 to 0.2 wt% of the single walled and from 0.01 to 0.35 wt% of the multi-walled nanotubes were dispersed in 1,4-butanediol (BD) by ultrasonication and by ultra high speed stirring. The nanocomposites were extruded followed by injection molding. The samples were characterized by electron microscopy and microindentation hardness techniques. The variations of the micromechanical properties (indentation hardness) of the nanocomposites with nanotube content and with temperature are discussed in the light of the stress transfer between the polymer matrix and nanotubes, the degree of dispersion, the nature of the tubes and other structural parameters.     

Actuators of individual carbon nanotubes

In this paper, actuation properties of carbon nanotubes are discussed. Samples of freestanding nanotubes on nanostructured metallic blocks have been prepared. Using a conducting AFM tip, electrons can be injected into the nanotubes. As a consequence, the nanotube expands in a similar way as buckypaper does in an electrolyte. From experimental data, the relative length change is estimated to be less than 1%. These findings are taken as a demonstration of an electromechanical actuator based on individual single walled carbon nanotubes.     

On the vibrations of single-walled carbon nanotubes

In this paper, a detailed numerical study on the free and forced vibrations of single walled carbon nanotubes is presented. A simple and straightforward method developed such that the proximity of the mathematical model to the actual atomic structure of the nanotube is significantly retained, is used for this purpose. Both zigzag and armchair chiralities of the carbon nanotubes for clamped-free and clamped-clamped boundary conditions are analyzed and their natural frequencies and corresponding mode shapes are obtained. Results pertaining to axial, bending, and torsional modes of vibration are reported with discussions. These modes of vibration appear in the eigen-values and eigen-vectors without any distinction. The direct integration method by Newmark is used extensively along with the fast Fourier transform to identify different types of vibrational modes. In the case of zigzag nanotubes, the axial, bending, and torsional modes appear to be decoupled, whereas the armchair nanotubes show coupling between such modes.     

Effect of carbon nanotubes dispersion on morphology, internal structure and thermal stability of electrospun poly(vinyl alcohol)/carbon nanotubes nanofibers

The current work reports the effect of multi walled carbon nanotubes and single walled carbon nanotubes dispersion on morphological, structural and thermal degradation of electrospun poly(vinyl alcohol) (PVA)/carbon nanotubes (CNTs) dispersed in sodium dodecyl sulfate (SDS) (PVA/CNTs–SDS) composites nanofibers. (PVA/CNTs–SDS) nanocomposites fibers were elaborated using the traditional electrospinning process to disperse and align CNTs into the fibers, especially for low CNTs loading fraction: 0.3 and 0.7 wt%. The morphology of the electrospun fibers was studied using the scanning electronic microscopy. The average diameter of the fibers changes significantly after the incorporation of the CNTs in the PVA. Furthermore, Fourier transform infrared spectroscopy elucidated the effect of CNTs on the crystallization of the PVA which was confirmed by X-ray diffraction analysis. Thermogravimetric analysis showed that the thermal stability of the composite fibers depends on the loading fraction and on the type of carbon nanotubes.     

不同激发波长下单壁碳纳米管与多壁碳纳米管的拉曼光谱比较

对不同激发波长下单壁和多壁碳纳米管的激光拉曼光谱进行了比较。发现单壁碳纳米管D峰强度和G峰强度的比值(ID/IG)几乎不随激发光子能量的改变而变化,多壁碳纳米管ID/IG值随着激发光子能量的增加以斜率0 3/eV减小。并对此现象进行了初步的分析。此外,还发现在1064nm激发波长下,单壁和多壁碳纳米管2500-3500cm-1之间拉曼峰的相对强度随着入射激光功率的增加而增加。