Synthesis of carbon nanofibers by ethanol catalytic combustion technique

Fei Li; Xiao-ping Zou; Jin Cheng; Hong-dan Zhang; Peng-fei Ren; Mao-fa Wang; Guang Zhu

doi:10.1007/s11771-008-0004-0

Journal of Central South University ›› 2008, Vol. 15 ›› Issue (1) : 15 -19. DOI: 10.1007/s11771-008-0004-0

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Synthesis of carbon nanofibers by ethanol catalytic combustion technique

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Abstract

A general, simple and economic synthetic method for synthesizing carbon nanofibers was presented. In the method, ethanol was employed as carbon source; metal salts such as nickel nitrate, ferric nitrate and ferric chloride were used as catalyst precursor respectively; copper plate was employed as the support material. A lot of products were obtained by catalytic combustion deposition of ethanol vapor. Then the as-prepared carbon nanofibers were characterized by field-emission scanning electron microscopy, transmission electron microscopy, Raman spectroscopy, energy dispersion X-ray spectroscopy and selected-area electron diffractometry. By analyzing the results of characterization, the conclusions are as follows: 1) the large catalyst particles tend to form large-diameter CNFs, small catalyst particles are inclinable to form small-diameter CNFs; 2) the morphology of the catalyst can affect the final morphology of the CNFs. Moreover, the possible growth mechanisms were proposed and the degree of graphitization of samples was estimated by Raman spectroscopy characterization.

Keywords

synthesis / ethanol catalytic combustion / carbon nanofibers / growth mechanism / degree of graphitization

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Fei Li, Xiao-ping Zou, Jin Cheng, Hong-dan Zhang, Peng-fei Ren, Mao-fa Wang, Guang Zhu. Synthesis of carbon nanofibers by ethanol catalytic combustion technique. Journal of Central South University, 2008, 15(1): 15-19 DOI:10.1007/s11771-008-0004-0

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References

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[1]	TeoK. B. K., SinghC., ChhowallaM., MilneW. I.Catalytic synthesis of carbon nanotubes and nanofibers[M], 2003, California, American Scientific Publishers: 1-22

[2]	ChambersA., RodriguezN. M., BakerR. T. K.. Influence of copper on the structural characteristics of carbon nanofibers produced from the cobalt-catalyzed decomposition of ethylene[J]. J Mater Res, 1996, 11(2): 430-438

[3]	RodriguezN. M., ChambersA., BakerR. T. K.. Catalytic engineering of carbon nanostructures[J]. Langmuir, 1995, 11(10): 3862-3866

[4]	KimM. S., RodriguezN. M., BakerR. T.. The interaction of hydrocarbons with copper-nickel and nickel in the formation of carbon filament[J]. Journal of Catalysts, 1991, 131(1): 60-73

[5]	BakerR. T. K.. Catalytic growth of carbon filaments[J]. Carbon, 1989, 27(3): 315-323

[6]	HeyningO. T., BernierP., GlerupM.. A low cost method for the direct synthesis of highly Y-branched nanotubes[J]. Chem Phys Lett, 2005, 409(1): 43-47

[7]	AjayanP. M.. How does a nanofiber grow[J]. Nature, 2004, 427(29): 402-403

[8]	RodriguezN. M.. A review of catalytically grown carbon nanofibers[J]. J Mater Res, 1993, 8(12): 3233-3250

[9]	ZhaoJ. C., LaiC. Y., DaiY., XieJ. Y.. Synthesis of mesoporous carbon as electrode material for supercapacitor by modified template method[J]. J Cent South Univ Technol, 2005, 12(6): 647-652

[10]	BakerR. T. K., PrestridgeE. B., GartenR. T.. Elelctron microscopy of supported metal particles: I. Behavior of Pt on titanium oxide, aluminum oxide, silicon oxide, and carbon[J]. Journal of Catalysis, 1979, 56(3): 390-406

[11]	WangY., SerranoS., Santiago-AvilésJ. J.. Raman characterization of carbon nanofibers prepared[J]. Synthetic Metals, 2003, 138(3): 423-427

[12]	DresselhausM. S., EklundP. C.. Phonons in carbon nanotubes phonons in carbon nanotubes[J]. Advances in Physics, 2000, 49(6): 705-814

[13]	JorioA., Souza FilhoA. G., DresselhausG., DresselhausM. S., SwanA. K., UnluM. S., GoldbergB. B., PimentaM. A., HafnerJ. H., LieberC. M., SaitoR.. G-band resonant Raman study of 62 isolated single-wall carbon nanotubes[J]. Phys Rev B, 2002, 65(155): 412

[14]	BoskovicB. O., StolojanV., ZezeD. A., ForrestR. D., SilvaS. R. P.. Branched carbon nanofibers network synthesis at room temperature using radio frequency supported microwave plasmas[J]. J Appl Phys, 2004, 96(6): 3443-3446

[15]	KishoreN., SachanS., RaiK. N., KumarA.. Synthesis and characterization of a nanofiltration carbon membrane derived from phenol-formaldehyde resin[J]. Carbon, 2003, 41(15): 2961-2972