Plasma Syntheses of Carbon Nanotube-Supported Pt-Pd Nanoparticles

It is reported that the highly dispersed Pt nanoparticles on carbon nanotubes can be synthesized under mild conditions by in situ plasma treatment.The carbon nanotube was pretreated by O_2 plasma to transform into oxide carbon nanotubes（O-CNTs）,and then it was mixed with the precursors（the mixture of H_2 PtCl_6and PdCl_6）.After that,the O-CNTs and the precursors were simultaneously treated by H_2 plasma.The precursors were transformed into Pt-Pd nanoparticles（NPs）and the O-CNTs transformed into CNT.The synthesized CNT-based Pt-Pd nanoparticles were characterized by scanning electron microscopy,transmission electron microscopy,X-ray diffraction and X-ray photoelectron spectroscopy.All the analysis showed that the Pt-Pd nanoparticles were deposited on CNT as a form of face-centered cubical structure.

Novel Method for Preparing a Carbon Nanotube-Supported Cobalt Catalyst for Fischer–Tropsch Synthesis:Hydrogen Dielectric-Barrier Discharge Plasma

Hydrogen dielectric-barrier discharge (H2-DBD) plasma was successfully used to prepare carbon nanotubes (CNTs)-supported cobalt (Co) catalyst. The H2-DBD plasma treatment simultaneously decomposed and reduced the cobalt precursor at a lower temperature and in a shorter time than the conventional method (calcination and hydrogen reduction). It is considered that the H2-DBD plasma method can remarkably decrease the amount of energy input compared to traditional methods used to prepare the Co-based catalyst in Fischer-Tropsch synthesis (FTS). Results showed that the Co catalyst prepared by H2-DBD plasma had an equivalent catalytic performance for FTS as that prepared using the conventional method in calcination and hydrogen reduction, thereby determining that H2-DBD plasma was an effective alternative treatment for preparing the Co/CNTs catalyst for FTS. This technology will provide a new strategy for preparing catalysts in other catalysis processes.

Fischer–Tropsch synthesis using Co and Co-Ru bifunctional nanocatalyst supported on carbon nanotube prepared via chemical reduction method

We used a chemical reduction method to synthesize the catalysts of cobalt(Co) and cobalt-ruthenium(Co-Ru) bifunctional supported on carbon nanotubes(CNTs) for Fischer–Tropsch synthesis(FTS) in a fixedbed reactor. These Co-Ru/CNTs catalysts were synthesized with various weight proportions of Ru/Co(0.1 to 0.4 wt%) with keeping a fixed amount of cobalt(10 wt%). Moreover, for comparison purpose, CNTs supported Co-and Co(Ru)-based catalysts at same loading as the above catalysts were prepared through impregnation method. We characterize the present catalysts through the various techniques such as Energy–dispersive X-ray(EDX), Transmission Electron Microscopy(TEM), Brunauer–Emmett–Teller(BET),Hydrogen-Temperature-Programmed Reduction(H_2-TPR), Hydrogen-Temperature-Programmed Desorption(H_2-TPD) and O_2 titration. Thus using the chemical reduction method, a narrow particle size distribution was obtained so that the small cobalt particles were confined inside the CNTs. The Co-based catalyst prepared by impregnation was compared with the Co-Ru catalysts at the same loading. The results demonstrated that the use of chemical reduction method led to decrease the average Co oxide cluster size to8.7 nm so that the reduction enhanced about 24% and stabilized an earlier time at the stream. Among the prepared catalysts, the results indicated that the Co-Ru/CNTs catalysts demonstrated high catalytic activity with the highest long-chain hydrocarbons(C_(5+)), selectivity up to 74.76%, which was higher than those we obtained by the Co-Ru/γ-Al_2O_3(61._20%), Co/CNTs(43.68%) and Co/γ-Al_2O_3(37.69%). At the same time, comparing with those catalyst synthesized by impregnation, the use of chemical reduction led to enhancement of the C_(5+) selectivity from 59.30% to 68.83% and increment in FTS rate about 11% for the Co-Ru/CNTs catalyst.

Carbon nanotubes decorated α-Al_2O_3 containing cobalt nanoparticles for Fischer-Tropsch reaction

A new hierarchical composite consisted of multi-walled carbon nanotubes （CNTs） layer anchored on macroscopic a-A1203 host matrix was synthesized and used as support for Fischer-Tropsch synthesis （FTS）. The composite constituted by a thin shell of a homogeneous, highly entan-gled and structure-opened carbon nanotubes network and it exhibited a relatively high and fully accessible specific surface area of 76 m2.g-1, compared with that of 5 m2.g-1 of the original a-A1203support. The metal-support interaction between carbon nanotubes surface and cobalt precursor and high effective surface area led to a relatively high dispersion of cobalt nanoparticles. This hierarchically supported cobalt catalyst exhibited a high FTS activity along with an extremely high selectivity towards liquid hydrocarbons compared with the cobalt-based catalyst supported on pristine a-A1203 or on CNTs carriers. This improvement can attribute to the high accessibility of composite surface area com- paring with the macroscopic host structure alone or to the bulk CNTs where the nanoscopic dimension induced a dense packing with low mass transfer which favoured the problem of reactants competitive diffusion towards the cobalt active site. In addition, intrinsic thermal conductivity of decorated CNTs could help the heat dissipating throughout the catalyst body, thus avoiding the formation of local hot spots which appeared in high CO conversion under pure syngas feed in FTS reaction. Cobalt supported on CNTs decorated a-A1203 catalyst also exhibited satisfied high stability during more than 200 h on stream under relatively severe conditions compared with other catalysts reported in the literature. Finally, the macroscopic shape of such composite easily rendered its usage as catalyst support in a fixed-bed configuration without facing problems of transport and pressure drop as encountered with the bulk CNTs.

Performance of Cobalt-Based Fischer-Tropsch Synthesis Catalysts Using Dielectric-Barrier Discharge Plasma as an Alternative to Thermal Calcination

Co-based catalysts were prepared by using dielectric-barrier discharge （DBD） plasma as an alternative method to conventional thermal calcination. The characterization results of N2-physisorption, temperature programmed reduction （TPR）, transmission electron microscope （TEM）, and X-ray diffraction （XRD） indicated that the catalysts prepared by DBD plasma had a higher specific surface area, lower reduction temperature, smaller particle size and higher cobalt dispersion as compared to calcined catalysts. The DBD plasma method can prevent the sintering and aggregation of active particles on the support due to the decreased treatment time （0.5 h） at lower temperature compared to the longer thermal calcination at higher temperature （at 500~C for 5 h）. As a result, the catalytic performance of the Fischer-Tropsch synthesis on DBD plasma treated Co/Si02 catalyst showed an enhanced activity, C5＋ selectivity and catalytic stability as compared to the conventional thermal calcined Co/SiO2 catalyst.

Ru particle size effect in Ru/CNT-catalyzed Fischer-Tropsch synthesis

Carbon nanotube （CNT）-supported Ru nanoparticles with mean sizes ranging from 2.3 to 9.2 nm were prepared by different post-treatments and studied for Fischer-Tropsch （FT） synthesis. The effects of Ru particle size on catalytic behaviors were investigated at both shorter and longer contact times. At shorter contact time, where the secondary reactions were insignificant, the turnover frequency （TOF） for CO conversion was dependent on the mean size of Ru particles; TOF increased with the mean size of Ru particles from 2.3 to 6.3 nm and then decreased slightly. At the same time, the selectivities to C5＋ hydrocarbons increased gradually with the mean size of Ru particles up to 6.3 nm and then kept almost unchanged with a further increase in Ru particle size. At longer contact time, C10-C20 selectivity increased significantly at the expense of C21＋ selectivity, suggesting the occurrence of the selective hydrocracking of C21＋ to C10-C20 hydrocarbons.

Synthesis of Single-Walled Carbon Nanotubes by Induction Thermal Plasma

The production of high quality single-walled carbon nanotubes(SWCNTs)on a bulk scale has been an issue of considerable interest.Recently,it has been demonstrated that high quality SWCNTs can be continuously synthesized on large scale by using induction thermal plasma technology.In this process,the high energy density of the thermal plasma is employed to generate dense vapor-phase precursors for the synthesis of SWCNTs.With the current reactor system,a carbon soot product which contains approximately 40 wt%of SWCNTs can be continuously synthesized at the high production rate of~100 g/h.In this article,our recent research efforts to achieve major advances in this technology are presented.Firstly,the processing parameters involved are examined systematically in order to evaluate their individual inuences on the SWCNT synthesis.Based on these results,the appropriate operating conditions of the induction thermal plasma process for an effective synthesis of SWCNTs are discussed.A characterization study has also been performed on the SWCNTs produced under the optimum processing conditions.Finally,a mathematical model of the process currently under development is described.The model will help us to better understand the synthesis of SWCNTs in the induction plasma process.

Solvent-free microwave-assisted synthesis of tenorite nanoparticle-decorated multi-walled carbon nanotubes

Copper-decorated carbon nanotubes(CNTs) have important applications as precursors for ultraconductive copper wires. Tenorite-decorated CNTs(CuO-CNTs) are ideal candidates and are currently developed using laborious processes. For this reason, we have developed a facile and scalable method for the synthesis of CuO-CNTs from copper acetate. It was found that the optimal loading of copper acetate onto the CNTs was 23.1 wt% and that three 1-minute microwave treatments were sufficient for the decomposition of copper acetate to copper oxide. The loading of copper oxide onto the nanotubes was confirmed using X-ray photoelectron spectroscopy, energy-dispersive X-ray spectroscopy and thermogravimetric analysis. The materials were characterised using X-ray diffraction and scanning electron microscopy.

Synthesis of (B-C-N) Nanomaterials by Arc Discharge Using Heterogeneous Anodes

In spite of the current prevalence of the CVD-based processes, the electric arc remains an interesting process for the synthesis of carbon nanoforms, thanks to its versatility, robustness and easiness. It also allows performing in-situ substitution of carbon atoms by hetero-elements in the graphene lattice. Our work aims to establish a correlation between the plasma properties, type and chemical composition （and the substitution rate） of the obtained single-wall carbon nan- otubes. The plasma was characterized by optical emission spectroscopy and the products were analyzed by high resolution transmission electron microscopy and core level Electron Energy-Loss Spectroscopy （EELS）. Results show that a high boron content leads to a plasma temperature decrease and hinders the formation of nanotubes. This effect can be compensated by increasing the arc current and/or yttrium content. The optimal conditions for the synthesis of boron- and/or nitrogen-substituted nanotubes correspond to a high axial plasma temperature associated to a strong radial gradient. EELS analysis confirmed that the boron incorporates into the graphenic lattice.

Improvement in growth yield of single-walled carbon nanotubes with narrow chirality distribution by pulse plasma CVD

A pulse plasma chemical vapor deposition (CVD) technique was developed for improving the growth yield of single-walled carbon nanotubes (SWNTs) with a narrow chirality distribution. The growth yield of the SWNTs could be improved by repetitive short duration pulse plasma CVD, while maintaining the initial narrow chirality distribution. Detailed growth dynamics is discussed based on a systematic investigation by changing the pulse parameters. The growth of SWNTs with a narrow chirality distribution could be controlled by the difference in the nucleation time required using catalysts comprising relatively small or large particles as the key factor. The nucleation can be controlled by adjusting the pulse on/ofF time ratio and the total processing time.

热解碳氢化合物技术制备生长于石墨基板表面的碳纳米管的研究

研究开发了有效的合成制备碳纳米管的技术。通过在石墨基板上化学沉积镍纳米粒子。在热解炉中,通以碳氢化合物气体作为碳来源物,以镍纳米粒子作为催化剂基种,在高温作用下,镍催化碳氢化合物热裂解沉积出碳元素,在镍纳米粒子上生长出碳纳米管。制备出植于石墨片基板上的多壁碳纳米管体系,碳纳米管长度一般在数微米以上,直径在20~30 nm。该技术可高效,便利且低成本制备出大批量的承载于石墨片的碳纳米管,便于后续应用于环境及电子领域。

用煤合成碳纳米管新方法

A new technique for the synthesis of carbon nanotubes from coal is introduced in this paper. In this process, coal is selected as the raw material to injected into plasma jet directly, nanotubes are formed on the reactor wall. The metal elements contained in parent coal such as Cu, Al act as the catalyst. This technique is different from the traditional arc discharge process and has the advantages of easy and steady operation and low cost of raw material, so it is an attractive process.

碳纳米管封装铁纳米粒子催化剂上CO加氢制低碳烯烃（英文）

由于石油资源的逐步枯竭,近年来费托(F-T)反应因其可以高效将煤、天然气和生物质等转化成液体燃料和高值化学品而越来越受到人们的关注.相比于Co,Ni和Ru等F-T催化剂,Fe基催化剂因其价格低廉,产物分布广而被广泛研究.以合成气直接制备低碳烯烃的F-T过程为例,铁基催化剂通常会因积碳和烧结的问题,而导致失活.因此,人们通常使用一些氧化物载体,比如氧化硅,氧化铝或者分子筛来分散并稳定铁粒子.但是这类氧化物载体通常与铁有非常强的相互作用,特别是在铁粒子较小的情况下,容易生成一些难于还原的硅酸铁和铝酸铁.而活性炭、碳纤维等惰性载体与铁的相互作用较弱,不足以稳定小的铁粒子在而反应过程中聚集.近来,我们组提出了利用石墨烯碳层封装过渡金属粒子作为催化剂,利用"穿透"的金属电子来催化反应,从而可以使活性中心和反应介质隔离,有效地增强了非贵金属催化剂的活性和稳定性.在此基础上,我们组和其他课题组的研究表明,一系列石墨烯碳层封装的非贵金属催化剂在燃料电池阴极氧还原反应,电催化析氢反应,染料敏化太阳能电池中的I–3还原反应以及催化氧化还原反应中都有着广泛的应用前景.这种材料中碳层不仅能在氧化气氛、酸性介质中保护包覆的金属,防止其被氧化或者腐蚀,还与包覆的金属有着较强的相互作用,可以促进非贵金属的电子向碳层表面的转移,有望在一些苛刻的反应条件下实现对贵金属催化剂的替代.本文进一步拓展了其在高温反应中的应用,发现豆荚状碳纳米管封装的金属铁纳米粒子在合成气制备低碳烯烃中可以有效防止金属铁纳米粒子的烧结和聚集,因此表现出优异的低碳烯烃选择性和催化稳定性.我们利用一步化学反应法合成了豆荚状碳纳米管封装的铁纳米粒子催化剂(Pod-Fe),并通过酸洗除去碳管外面裸露的铁粒子.透射电镜(TEM)和X射线衍射(XRD)表明酸洗后铁粒子被包覆在碳管内,并且呈金属态,而酸洗前,则还有大量的氧化铁粒子分布于碳管外部(Fe Ox/Pod-Fe).将酸洗前后的两个催化剂用于固定床气相F-T反应中.通过调节空速和温度考察了它们的催化反应性能,结果表明两个催化剂在不同的反应条件下都有着良好的低碳烯烃选择性.不同反应温度下,它们表现出不同的变化趋势:Pod-Fe活性随着温度的升高而缓慢增长,至380 oC都没有明显的失活现象;而对于Fe Ox/Pod-Fe催化剂,随着温度的升高,CO的转化率先升高,在300 oC时达最高,但随着温度进一步升高,活性迅速降低,呈现一个火山型曲线.TEM结果发现,反应后Fe Ox/Pod-Fe催化剂粒子上产生了很多杂乱的碳丝,并且铁粒子有着明显的聚集长大.而Pod–Fe催化剂即使在380 oC反应后,其形貌仍然保持完好,没有积碳产生,粒子也没有发生聚集和长大.进一步在320 oC下120 h的寿命试验发现,Pod-Fe催化剂的初始活性较低,但经20 h的活化阶段,活性会先增加后略有下降,20 h后趋于稳定.而Fe Ox/Pod-Fe催化剂在反应初始虽然表现出较高的活性,但是随着时间进行,活性迅速下降一半以上,最后趋于稳定.同时结合反应后TEM和XRD的结果发现碳管外部裸露的铁粒子会在反应过程中形成碳化铁物种,并随着反应进行产生聚集,并伴有大量积碳,导致活性迅速下降;而碳层的包覆对于铁粒子有着很好的稳定作用,使得铁粒子能够在高温反应中保持稳定,并且没有积碳的产生.由此可见石墨烯碳层可以有效保护其包覆的金属粒子,并且能够提高其在高温反应下的低碳烯烃选择性和稳定性.此类催化剂有望在一些苛刻条件下的多相催化反应中得到广泛应用.

微波等离子体化学气相沉积法低温合成纳米碳管

纳米碳管的低温合成是纳米碳管合成的一个重要研究方向 .在众多的合成方法中 ,化学气相沉积法 ,特别是等离子体化学气相沉积法在纳米碳管的低温合成方面意义重大 .本研究利用溶胶 -凝胶法结合等离子体还原 ,获得了负载在SiO2 上的纳米金属钴颗粒 .以甲烷为碳源、氢气为载气 ,在纳米金属钴颗粒的催化作用下 ,利用微波等离子体化学气相沉积法在低于 5 0

XC-72碳和碳纳米管负载PtRu纳米粒子的微波快速合成及其对甲醇的电化学氧化

利用微波辐射加热技术快速合成了XC 72碳和碳纳米管 (CNTs)负载的PtRu合金纳米粒子 ,合金负载的质量分数为2 0 % ,Pt和Ru的原子比接近于 1∶1.透射电镜观察表明微波合成的PtRu合金纳米粒子具有细小的粒径和狭窄的尺寸分布 ,所合成的PtRu合金纳米粒子高度分散在XC 72碳和CNTs的表面 ,其平均粒径分别为 3 .3nm和 2 .8nm .电化学实验表明微波合成的PtRu/XC

SiO_2负载纳米Co催化剂的制备

以正硅酸乙酯和硝酸钴等为原料 ,利用溶胶 凝胶法合成了含钴物质均匀分散的SiO2 凝胶。在适当的条件下利用微波等离子体还原 ,获得了结构比较疏松的SiO2 载体材料 ,其上负载的金属钴颗粒具有较规则的球形以及均一的粒度 ,适宜用作合成纳米碳管的催化剂。

等离子体法制备碳纳米管负载银粒子及抑菌性研究

通过温和的等离子体法制备出碳纳米管负载纳米银粒子,并研究了其对大肠杆菌的抑制作用。首先用氧等离子体处理碳纳米管,再将银离子负载在碳纳米管表面上,接着用氢等离子体将负载的银离子还原成纳米银粒子。用TEM和XRD对制备出的银粒子进行表征,研究表明,平均粒径为5nm左右的银粒子负载在碳纳米管表面。对大肠杆菌的抑菌实验表明,Ag-CNTs浓度大于1μg/mL时,对大肠杆菌生长抑制效果明显。

碳纳米管负载纳米CdSe复合材料的微波合成及其光催化性能

以CNTs为模板,硒粉(Se)和硝酸镉[Cd(NO3)2]为原料,水合肼和氨水分别作为还原剂和络合剂,采用微波法合成了CNTs负载CdSe纳米粒子复合材料(CdSe/CNTs,简称F),其结构经XRD,SEM和EDS表征。以酸性品红为目标降解物,用UV-Vis法研究了F的光催化性能。结果表明,在紫外灯下照射60 min,F对酸性品红的降解率达99%,比CdSe纳米粒子高出38%。

Nanothermite colloids: A new prospective for enhanced performance

Nanothermites (metal oxide/metal) can offer tremendously exothermic self sustained reactions. CuO is one of the most effective oxidizers for naonothermite applications. This study reports on two prospectives for the manufacture of CuO nanoparticles. Colloidal CuO particles of 15 nm particle size were developed using hydrothermal synthesis technique. Multiwalled carbon nanotubes (MWCNTs) with surface are 700m2/g was employed as a substrate for synthesis of CuO-coated MWCNTs using electroless plating. On the other hand, aluminium particles with combustion heat of 32000 J/g is of interest as high energy density material. The impact of stoichiometric nanothermite particles (CuO/Al & Cuo-coated MWCNTs/Al) on shock wave strength of Al/TNT nanocomposite was evaluated using ballistic mortar test. While CuO-coated MWCNTs decreased the shock wave strength by 15%;colloidal CuO enhanced the shock wave strength by 30%. The superior performance of colloidal CuO particles was correlated to their steric stabilization with employed organic solvent. This is the first time ever to report on fabrication, isolation, and integration of stablilized colloidal nanothermite particles into energetic matrix where intimate mixing between oxidizer and metal fuel could be achieved.

鲁米诺-还原金纳米粒子/碳纳米管三维复合材料基电化学发光传感器检测血清中的乳酸

采用一锅水热法制备了鲁米诺-还原金纳米粒子/碳纳米管三维复合材料(Lu-AuNPs/CNTs),用其制备固态电化学发光(ECL)传感器,并用于血清中乳酸的检测。采用场发射扫描电子显微镜(FSEM)、透射电子显微镜(TEM)、X射线粉末衍射仪(XPS)和X射线光电子能谱仪(EDS)对Lu-AuNPs/CNTs的形貌、结构、尺寸进行了表征。结果表明,碳纳米管(CNTs)为三维立体网状结构,鲁米诺-还原金纳米粒子(Lu-AuNPs)尺寸均一地分布在CNTs的表面。将Lu-AuNPs/CNTs固定在玻碳电极表面制成固态ECL传感器,其电化学发光信号约是Lu-AuNPs的2倍。该传感器的电化学发光强度与溶液中H2O2浓度成正比,线性范围为0.5~200μmol/L,检测限为0.2μmol/L。Lu-AuNPs/CNTs可用于固定乳酸氧化酶,所制备的传感器对乳酸的检测限为3.0μmol/L。该生物传感器可用于人血清样品中乳酸的测定。