用低温加氢裂解法在AFI分子筛孔道中制备单壁碳纳米管的影响因素

doi:10.11901/1005.3093.2016.438

材料研究学报

2017, Vol. 31

Issue (6): 401-409 DOI: 10.11901/1005.3093.2016.438

本期目录 | 过刊浏览

用低温加氢裂解法在AFI分子筛孔道中制备单壁碳纳米管的影响因素

杨文申,郎林,阴秀丽(

),吴创之

中国科学院广州能源研究所中国科学院可再生能源重点实验室广东省新能源和可再生能源研究开发与应用重点实验室广州 510640

Influencing Factors on Formation of SWCNTs in the Channels of AFI Molecular Sieves by Low-temperature Hydrocracking

Wenshen YANG,Lin LANG,Xiuli YIN(

),Chuangzhi WU

Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences, CAS Key Laboratory of Renewable Energy, Guangdong Provincial Key Laboratory of New and Renewable Energy Research and Development, Guangzhou 510640, China

引用本文:

杨文申,郎林,阴秀丽,吴创之. 用低温加氢裂解法在AFI分子筛孔道中制备单壁碳纳米管的影响因素[J]. 材料研究学报, 2017, 31(6): 401-409.
Wenshen YANG, Lin LANG, Xiuli YIN, Chuangzhi WU. Influencing Factors on Formation of SWCNTs in the Channels of AFI Molecular Sieves by Low-temperature Hydrocracking[J]. Chinese Journal of Materials Research, 2017, 31(6): 401-409.

全文: PDF(1908 KB) HTML

摘要:

用水热合成法制备出多种AFI型(AlPO₄-5、CoAPO-5、SAPO-5、CrAPO-5、FeAPO-5及MnAPO-5)分子筛,并系统研究了低温加氢裂解法在其孔道中制备直径为0.4 nm单壁碳纳米管(SWCNTs)的各种影响因素。使用XRD、NH₃-TPD及Raman等手段,研究了活性金属种类、活性金属添加量、反应温度和模板剂碳含量对所制备样品中SWCNTs的质量和填充密度的影响。结果表明,Si或活性金属的添加可改变AlPO₄-5分子筛的酸催化活性,进而影响低温加氢裂解法制备SWCNTs的质量和填充密度。加氢裂解温度和模板剂碳含量,也是影响SWCNTs制备的关键因素。

关键词 ：无机非金属材料, AFI分子筛, 单壁碳纳米管, IRBM/IG, 低温加氢裂解

Abstract：

AFI (AlPO₄-5, CoAPO-5, SAPO-5, CrAPO-5, FeAPO-5 and MnAPO-5) molecular sieves were synthesized by hydrothermal method, and then single-walled carbon nanotubes (SWCNTs) with a diameter of 0.4 nm were prepared in the channels of these kind molecular sieves by low-temperature hydrocracking. The effect of the type and the amount of active metals, the hydrocracking temperature and the carbon content of template agents was investigated by means of XRD, NH₃-TPD and micro-Raman spectroscopy. The results show that the addition of Si or active metal can improve the quantities of acid sites in the AFI molecular sieves, which can improve the density and quality of the SWCNTs in the channels of the hydrocracked AlPO4-5 molecular sieves. Besides, the hydrocracking temperature and the carbon content of template agents are also key influence factors for the preparation of SWCNTs.

Key words： inorganic non-metalic materials AFI molecular sieves SWCNTs IRBM/IG low-temperature hydrocracking

收稿日期: 2016-07-25

基金资助:国家自然科学基金(51661145022)和广东省科技计划(2016A010104011)

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图1 低温加氢裂解法制备SWCNTs的工艺流程图

表1 AFI分子筛的合成液配比和产物分析

图2 分子筛样品的XRD谱图

图3 在350℃加氢裂解处理后分子筛样品中SWCNTs的拉曼谱图

图4 CoAPO4-5(TEA)及FeAPO4-5(TEA)分子筛样品的XRD谱图

图5 在350℃加氢裂解处理后CoAPO4-5(TEA)及FeAPO4-5(TEA)分子筛样品中SWCNTs的拉曼光谱图

表2 在不同AFI分子筛晶体孔道中制备的SWCNTs拉曼特征峰值(IRBM,IG)和IRBM/IG值

图6 不同Co/Al的CoAlPO-5分子筛的NH3-TPD谱图

图7 在不同温度下AlPO4-5(TEA)和AlPO4-5(TPA)分子筛中制备的SWCNTs拉曼谱图

表3 不同Co/Al和Fe/Al的金属杂化AlPO4-5(TEA)分子筛孔道中制备的SWCNTs的拉曼特征峰值(IRBM,IG)及IRBM/IG值

表4 不同温度(280,300,320,350及400℃)下在AlPO4-5(TEA)和AlPO4-5(TPA)分子筛孔道中制备的SWCNTs拉曼特征峰值(IRBM,IG)及IRBM/IG值

[1]	Iijima S.Growth of carbon nanotubes[J]. Mat. Sci. Eng. B, 1993, 19(1): 172
[2]	Awasthi K, Srivastava A, Srivastava O J.Synthesis of carbon nanotubes[J]. J. Nanosci. Nanotechnol., 2005, 10: 1616
[3]	Azam M A, Manaf N S A, Taalib E, et al. Aligned carbon nanotube from catalytic vapor deposition technique for energy storage device: a review[J]. Ionics, 2013, 11: 1455
[4]	Tan L L, Ong W J, Chai S P, et al.Growth of carbon nanotubes over non-metallic based catalysts: a review on the recent developments[J]. Catal. Today., 2013, 217: 1
[5]	Guo T, Nikolaev P, Thess A, et al.Catalytic growth of single-walled nanotubes by laser vaporation[J]. Chem. Phys. Lett., 1995, 243: 49
[6]	Ebbesen T W, Ajayan P M.Large-scale synthesis of carbon nanotubes[J]. Nature, 1992, 358: 220
[7]	Ivanov V, Nagy J B, Lambin P, et al.The study of carbon nanotubes produced by catalytic method[J]. Chem. Phys. Lett., 1994, 223: 329
[8]	Tang Z K, Sun H D, Wang J, et al.Mono-sized single-wall carbon nanotubes formed in the channels of AlPO4-5 single crystals[J]. Appl. Phys. Lett., 1998, 73: 2287
[9]	Wang Z, Shi W, Lortz R, et al.Superconductivity in 4-angstrom carbon nanotubes-a short review[J]. Nanoscale, 2012, 4: 21
[10]	Zhang T, Sun M Y, Wang Z, Shi W, Sheng P.Crossover from Peierls distortion to one-dimensional superconductivity in arrays of (5, 0) carbon nanotubes[J]. Phys. Rev. B., 2011, 84: 245
[11]	Xu R R, Pang W Q.Chemistry-zeolites and Porous Materials[M]. Beijing: Beijing Science Press, 2004
[11]	(徐如人, 庞文琴. 分子筛与多孔材料化学 [M]. 北京: 北京科学出版社, 2004)
[12]	Zhai J P, Tang Z K, Hu X J, et al.Catalytic growth of 0.4 nm single-walled carbon nanotubes aligned inside porous zeolite crystals[J]. Phys. Stat. Sol (b)., 2006, 243: 3082
[13]	Yang W S, Liu X F, Zhang L, et al.In situ synthesis and microstructure manuipulation of SAPO-5 films over Porous α-Al2O3 substrates[J]. Langmuir, 2009, 25(4): 271
[14]	Li Z M, Zhai J P, Liu H J, et al.Synthesis of 4 ? single-walled carbon nanotubes in catalytic Si-substituted AlPO4-5 molecular sieves[J]. Appl. Phys. Lett., 2004, 85(7): 1253
[15]	Zhai J P, Li Z M, Liu H J, et al.Catalytic effect of metal cations on the formation of carbon nanotubes inside the channels of AlPO4-5 crystal[J]. Carbon, 2006, 44: 1151
[16]	Zhai J P, Tang Z K, Li Z M, et al.Carbonization of mechanism of Tetrapropylammonium-hydroxide in channels of AlPO4-5 single crystals[J]. Chem. Mater., 2006, 18: 1505
[17]	Chen Q H, Wang Z, Zheng Y, et al.New developments in the growth of 4 Angstrom carbon nanotubes in linear channels of zeolite template[J]. Carbon, 2014, 76: 401
[18]	Li G D, Tang Z K, Wang N, et al.Structural study of the 0.4 nm single-wall carbon nanotubes aligned in channels of AlPO4-5 crystal[J].Carbon, 2002, 40: 917
[19]	Yang W S, Sun W N, Zhao S H, et al.Single-walled carbon nanotubes prepared in small AlPO4-5 and CoAPO-5 molecular sieves by low-temperature hydrocracking[J]. Micropor. Mesopor. Mat., 2016, 219: 87
[20]	Fan W B, Li R F, Dou T, et al.Solvent effects in the synthesis of CoAPO-5, -11 and -34 molecular sieves[J]. Micropor. Mesopor. Mat., 2005, 84: 116
[21]	Hochtl M, Jentys A, Vinek H.Acidity of SAPO and CoAPO molecular sieves and their activity in the hydroisomerization of n-heptane[J]. Micropor. Mesopor. Mat., 1999, 31(3): 271

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