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用作催化剂载体的碳纳米管-氧化铝复合材料的制备 被引量:1

Preparation of CNTs-alumina composites used catalyst support
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摘要 用负载有Ni—Cu双活性金属的δ,θ-Al2O3作为催化剂,考察以化学气相沉积法合成碳纳米管-氧化铝复合材料的制备条件.实验表明,在Ni—Cu活性组分负载量为10‰(质量分数),Ni:Cu=4:1(质量比),反应温度730℃、反应气组分为C2H2:H2=25:75条件下反应30min,所生成的碳纳米管最好,得碳率可达15.7%.采用XRD、TGA/DTG等方法对生成的CNTs和复合材料的结构进行表征.结果表明:在所合成的碳纳米管-氧化铝复合材料中,碳纳米管在氧化铝载体的表面呈均匀覆盖,管径大小均匀,其外径约为60nm,而且碳纳米管间相互缠绕.与δ,θ-Al2O3基体相比,复合材料的比表面积由82.1增加到106.2m^2/g;比孔容积略有减小,出现了一类较小的中孔(1.6—2.1nm)结构. The preparation conditions of CNTs - alumina composites, which were synthesized by CVD using the Ni - Cu dual active metal supported on δ,θ-Al2O3 as catalysts, were investigated. The results showed that the most graphitization degree of CNTs was obtained using the total Ni and Cu metal loading of 10 wt‰, Ni: Cu =4:1 (mass ratio)with the reaction stream of C2H2: H2 =25:75 at 730 ℃ for 30 min, and the carbon yield can reach up to about 15.7%. The CNTs and CNTs-alumina composites were characterized by XRD, TGA/DTG, SEM and N2 physisorption. The results showed that in the composites the CNTs were distributed uniformly on the surface of alumina. The CNTs tubes had uniform external diameter of - 60 nm, and entangled each other. Compared to the bare δ,θ-Al2O3, the BET surface area of CNTs - alumina composites increased from 82. 1 m^2/g to 106.2 m^2/g, the pore volume of composite slightly decreased, moreover, a new smaller mesopore (1.6 - 2.1 nm) appeared.
作者 林磊 王榕 林炳裕 黄勤 魏可镁
机构地区 福州大学化肥催化剂国家工程研究中心
出处 《福州大学学报(自然科学版)》 CAS CSCD 北大核心 2009年第2期277-285,共9页 Journal of Fuzhou University(Natural Science Edition)
基金 国家自然科学基金资助项目(20576021) 国家科技支撑计划资助项目(2007BAE08B02) 福建省科技重大专项资助项目(2005HZ01)
关键词 碳纳米管 化学气相沉积法 δ θ-Al2O3 复合材料 催化剂载体 carbon nanotubes chemical vapor deposition δ,θ-Al2O3 composites catalyst support
分类号 O643 [理学—物理化学]
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  • 1Jianmei Wang Rong Wang Xiujin Yu Jianxin Lin Feng Xie Kemei Wei.Preparation and Characterization of Carbon Nanotubes-Coated Cordierite for Catalyst Supports[J].Journal of Natural Gas Chemistry,2006,15(3):211-216. 被引量:4
  • 2Kadowaki Y,Aika K.Promoter effect of Sm2O3 on Ru/Al2O3 in ammonia synthesis[J].J Catal,1996,161:178-185.
  • 3Niwa Y,Aika K.Ruthenium catalyst supported on CeO2 for ammonia synthesis[J].Chem Let,1996:3-4.
  • 4Murata S,Aika K.Removal of chlorine ions from Ru/MgO catalysts for ammonia synthesis[J].Appl Catal A:General,1992,82:1-12.
  • 5Miyazaki A,Balint L,Aika K,Nakano Y.Preparation of high activity catalyst for ammonia synthesis by supporting well-defined Ru nanoparticles on γ-Al2O3[J].Chem Let,2001:1332-1333.
  • 6Fishel C T,Davis R J,Garces J M.Ammonia synthesis catalyzed by ruthenium supported on basic zeolites[J].J Catal,1996,163:148-157.
  • 7Jacobsen C J H.Process for the preparation of ammonia[P].EP:1095 906A2,2001.
  • 8Zeng H S,Inazu K,Aika K.Dechlorination process of active carbon-supported,barium nitrate-promoted ruthenium trichloride catalyst for ammonia synthesis[J].Appl catal A,2001,219(1-2):235-247.
  • 9Murata S, Aika K.Preparation and characterization of chlorine-free ruthenium catalysts and the promoter effect in ammonia synthesis[J].J Catal,1992,136:118-125.
  • 10Hemadi K, Thien - Nga L, Forro L. Growth and microstructure of catalytically produced coiled carbon nanotubes [ J ]. J Phys Chem B, 2001, 105 : 12 464 - 12 468.

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  • 1王红强,颜志雄,李庆余,张安娜,代启发.新型锡/碳复合材料的制备及其用于锂离子电池负极材料的研究[J].化工新型材料,2007,35(8):8-9. 被引量:6
  • 2Hsieh C T,Chou Y W, Lin J Y. Fabrication and electrochemicalactivity of Ni-attached carbon nanotube electrodes for hydrogen storage in alkali electrolyte[J']. International Journal of Hydro- gen Energy,2007,32(15) :3457-3464.
  • 3Surya V J,Iyakutti K,Venkataramanan N,et al. The role of Li and Ni metals in the adsorbate complex and their effect on the hydrogen storage capacity of single walled carbon nanotubes coated with metal hydrides, LiH and NiH2 [J]. International Journal of Hydrogen Energy, 2010,35(6) : 2368-2376.
  • 4Liu H,Cheng G,Zheng R, et al. Influence of acid treatments of carbon nanotube precursors on Ni/CNT in the synthesis of car- bon nanotubes[J]. Journal of Molecular Catalysis A:Chemical, 2005,230(1-2) : 17-22.
  • 5Wang D W, Li F, Wu Z S, et al. Electrochemical interfaeial ca- pacitance in multilayer graphene sheets:Dependence on number of stacking layers[J]. Electrochemistry Communications, 2009, 11(9) :1729-1732.
  • 6Neto A H C,Guinea F,Peres N M R,et al. The electronic prop- erties of graphene[J]. Reviews of Modern Physics, 2009,81: 109-162.
  • 7Balandin A A,Ghosh S, Bao W, et al. Superior thermal conduc- tivity of single-ayer graphene[J]. Nano Letters, 2008, 18 (3) : 9O2-9O7.
  • 8Novak I,Krupa I. Electro-conductive resins filled with graphite for casting applications[J]. European Polymer Journal, 2004,40 (7) : 1417-1422.
  • 9Hummers Jr W S, Offeman R E. Preparation of graphitic oxide [J]. Journal of the American Chemical Science, 1958,80 (6): 1339.
  • 10于美,刘鹏瑞,孙玉静,刘建华,安军伟,李松梅.石墨烯银纳米粒子复合材料的制备及表征[J].无机材料学报,2012,27(1):89-94. 被引量:34

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福州大学学报(自然科学版)
2009年 第2期

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