Optimization of Flame Synthesis for Carbon Nanotubes Using Supported Catalyst

Wal, Randy L. Vander; Hall, Lee J.; Berger, Gordon M.

doi:10.1021/jp020614l

Cited by 98 publications

(55 citation statements)

References 57 publications

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“…CNFs are usually obtained by the chemical vapour deposition [7] (CVD) method from the decomposition of gaseous hydrocarbon over metal catalyst particles. Other methods such as flame synthesis [8], arc discharge [9] and laser ablation [10] have also been used to synthesize CNFs and CNTs, but they are energy intensive, expensive and yield less when compared to CVD. The catalytic growth of CNFs mechanism is well established and contains several steps as follows: (i) a carbon source is decomposed on the surface of transition metal nanoparticles, (ii) liquidised metal carbide is formed by diffusion of carbon atoms into the nanoparticles, (iii) after over saturation or due to cooling down of the particles, the carbon precipitates to form polyaromatic layers (graphenes).…”

Section: Introductionmentioning

confidence: 99%

Large Scale Synthesis of Carbon Nanofibres on Sodium Chloride Support

Rajarao

Bhat

2012

Nanomaterials and Nanotechnology

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Large scale synthesis of carbon nanofibres (CNFs) on a sodium chloride support has been achieved. CNFs have been synthesized using metal oxalate (Ni, Co and Fe) as catalyst precursors at 680 C by chemical vapour deposition method. Upon pyrolysis, this catalyst precursors yield catalyst nanoparticles directly. The sodium chloride was used as a catalyst support, it was chosen because of its non-toxic and water soluble nature. Problems, such as the detrimental effect of CNFs, the detrimental effects on the environment and even cost, have been avoided by using a water soluble support. The structure of products was characterized by scanning electron microscopy, transmission electron microscopy and Raman spectroscopy. The purity of the grown products and purified products were determined by the thermal analysis and X-ray diffraction method. Here we report the 7600, 7000 and 6500 wt% yield of CNFs synthesized over nickel, cobalt and iron oxalate. The long, curved and worm shaped CNFs were obtained on Ni, Co and Fe catalysts respectively. The lengthy process of calcination and reduction for the preparation of catalysts is avoided in this method. This synthesis route is simple and economical, hence, it can be used for CNF synthesis in industries.

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Section: Introductionmentioning

confidence: 99%

Large Scale Synthesis of Carbon Nanofibres on Sodium Chloride Support

Rajarao

Bhat

2012

Nanomaterials and Nanotechnology

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“…Premixed flame synthesis methods have certain advantages over the diffusion flame method, including the availability of a broad range of fuels, continuous and multistaged processing, scalability of stoichiometry of reagent gases, flame temperature (can be reduced by using chimneys), reactive gas profile, and equivalent ratio [72].…”

Section: Premixed Flame Synthesismentioning

confidence: 99%

“…In other studies, substrate-supported catalyst methods were used [72,81,84]. The substrate can also interact physically or chemically with the catalyst particles and may control their catalytic activity.…”

Section: Premixed Flame Synthesismentioning

confidence: 99%

Carbon nanotubes synthesis using diffusion and premixed flame methods: a review

Mittal¹,

Dhand²,

Rhee³

et al. 2015

Carbon letters

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In recent years, flame synthesis has absorbed a great deal of attention as a combustion method for the production of metal oxide nanoparticles, carbon nanotubes, and other related carbon nanostructures, over the existing conventional methods. Flame synthesis is an energyefficient, scalable, cost-effective, rapid and continuous process, where flame provides the necessary chemical species for the nucleation of carbon structures (feed stock or precursor) and the energy for the production of carbon nanostructures. The production yield can be optimized by altering various parameters such as fuel profile, equivalence ratio, catalyst chemistry and structure, burner configuration and residence time. In the present report, diffusion and premixed flame synthesis methods are reviewed to develop a better understanding of factors affecting the morphology, positioning, purity, uniformity and scalability for the development of carbon nanotubes along with their correlated carbonaceous derivative nanostructures.

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“…This method is based o controlled flame environment, that produces the temperature, forms the carbon atoms from the inexpensive hydrocarbon fuels and forms small aerosol metal catalyst islands [22,23]. SWNT are grown on these metal islands in the same manner as in laser ablation and arc discharge.…”

mentioning

confidence: 99%

“…These metal catalyst islands can be made in three ways. The metal catalyst (cobalt) can either be coated on a mesh [22], on which metal islands resembling droplets were formed by physical vapor deposition. These small islands become aerosol after exposure to a flame.…”

mentioning

confidence: 99%

Production of Carbon Nanotubes by Different Routes-A Review

Rafique¹,

Iqbal²

2011

JEAS

114

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Carbon Nanotubes are one the most important materials of future. Discovered in 1991, they have reached a stage of attracting the interests of many companies world wide for their large scale production. They possess remarkable electrical, mechanical, optical, thermal and chemical properties, which make them a perfect "fit" for many engineering applications. In this paper various methods of production of carbon nanotubes are discussed outlining their capabilities, efficiencies and possible exploitation as economic large scale production methods. Chemical vapor disposition (CVD) is proposed as a potential method for economic large scale production of carbon nanotubes due to its relative simplicity of operation, process control, energy efficiency, raw materials used, capability to scale up as large unit operation, high yield and purity.

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Optimization of Flame Synthesis for Carbon Nanotubes Using Supported Catalyst

Cited by 98 publications

References 57 publications

Large Scale Synthesis of Carbon Nanofibres on Sodium Chloride Support

Large Scale Synthesis of Carbon Nanofibres on Sodium Chloride Support

Carbon nanotubes synthesis using diffusion and premixed flame methods: a review

Production of Carbon Nanotubes by Different Routes-A Review

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