CARBON NANOTUBES VIA METHANE DECOMPOSITION ON AN ALUMINA SUPPORTED COBALT AEROGEL CATALYST 被引量：2

CARBON NANOTUBES VIA METHANE DECOMPOSITION ON AN ALUMINA SUPPORTED COBALT AEROGEL CATALYST

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摘要 An alumina-supported cobalt aerogel catalyst prepared from a sol-gel and a supercritical drying method was used in the catalytic decomposition of methane. The physical-chemical properties of the catalyst were characterized and its activity for methane decomposition was investigated. The effects of calcination and reaction temperatures on the activity of the catalyst and the morphology of the carbon nanotubes produced were discussed. A CoAl2O4 spinel structure formed in the calcined catalyst. The quantity of the nanotubes produced in the reaction increases with the amount of cobalt in the reduced catalyst. A higher reaction temperature leads to a higher reaction rate, though faster deactivation of the catalyst occurs with the change. The carbon nanotubes grown on the catalyst have smooth walls and uniform di-ameter distribution. An alumina-supported cobalt aerogel catalyst prepared from a sol-gel and a supercritical drying method was used in the catalytic decomposition of methane. The physical-chemical properties of the catalyst were characterized and its activity for methane decomposition was investigated. The effects of calcination and reaction temperatures on the activity of the catalyst and the morphology of the carbon nanotubes produced were discussed. A CoAl2O4 spinel structure formed in the calcined catalyst. The quantity of the nanotubes produced in the reaction increases with the amount of cobalt in the reduced catalyst. A higher reaction temperature leads to a higher reaction rate, though faster deactivation of the catalyst occurs with the change. The carbon nanotubes grown on the catalyst have smooth walls and uniform di-ameter distribution.

作者 Lingyu Piao Jiuling Chen Yongdan Li

机构地区 Department of Catalysis Science and Technology

出处《China Particuology》 SCIE EI CAS CSCD 2003年第6期266-270,共5页

基金 supports from a 973 Program of the Chinese Ministry of Science and Technology under contract number G199902240 National Natural Science Foundation of China under contract numbers 20006072,29792079-2 and 29876032 are gratefully acknowledged.

关键词 catalytic decomposition METHANE carbon nanotubes SOL-GEL AEROGEL cobalt catalyst morphology catalytic decomposition methane carbon nanotubes sol-gel aerogel cobalt catalyst morphology

分类号 O613.71 [理学—无机化学]

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参考文献17

1[1]Alvarez,W.E.,Kitiyanan,T.,Borgna,A.& Resasco,D.E.(2001).Synergism of Co and Mo in the catalytic production of single-wall carbon nanotubes by decomposition of CO.Carbon,39,547-558.
2[2]Amelinckx,S.,Zhang,X.B.,Bernaerts,D.,Zhang,X.F.,Ivanov,V.& Nagy,J.B.(1995).A formation mechanism for catalytically grown helix-shaped graphite nanotubes.Science,265,635-639.
3[3]Avdeeva,L.B.,KoChubey,D.I.& Shaikhutdinov,S.K.(1999).Cobalt catalysts of methane decomposition:accumulation of the filamentous carbon.Appl.Catal.A:General,177,43-51.
4[4]Chen,J.L.,Li,X.M.,Li,Y.D.& Qin,Y.N.(2003).Production of hydrogen and nanocarbon from direct decomposition of undiluted methane on high-nickeled Ni-Cu-alumina catalysts.Chem.Lett.,32,424-425.
5[5]Colbert,D.T.& Smalley,R.E.(1995).Catalytic growth of single-walled nanotubes by laser vaporization.Chem.Phys.Lett.,243,49-54.
6[6]Dai,H.,Rinzler,A.G.,Nikolaev,P.,Thess,A.,Colbert,D.T.&Smalley,R.E.(1996).Single-wall nanotubes produced by metal-catalyzed disproportionation of carbon monoxide.Chem.Phys.Lett.,260,471-475.
7[7]Hernadi,K.,Fonseca,A.,Nagy,J.B.,Bernaerts,D.,Fudala,A.&Lucas,A.A.(1996).Catalytic synthesis of carbon nanotubes using zeolite support.Zeolites,17,416-423.
8[8]lijima,S.(1991).Helical microtubes of graphitic carbon.Nature,354,56-58.
9[9]Laurent,Ch.,Flahaut,E.,Peigney,A.& Rousse,A.(1998).Metal nanoparticles for the catalytic synthesis of carbon nanotubes.New J.Chem,1229-1237.
10[10]Li,Y.D.,Chen,J.L.,Ma,Y.M.,Zhao,J.B.,Qin,Y.N.& Chang,L.(1999).Formation of bamboo-like nanocarbon and evidence for the quasi-liquid state of nanosized metal particles at moderate temperatures.Chem.Commun.,1141-1142.

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CARBON NANOTUBES VIA METHANE DECOMPOSITION ON AN ALUMINA SUPPORTED COBALT AEROGEL CATALYST 被引量：2

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