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Progress in Chemistry 2005, Vol. 17 Issue (04): 666-671 Previous Articles   Next Articles

• Review •

The Catalytic Application and Synthesis Strategies of Nano-Size Zeolites

Liu Yunqi**;Liu Chunying;Liu Chenguang   

  1. CNPC Key Laboratory of Catalysis, College of Chemistry and Chemical Engineering, China University of Petroleum (East China),Dongying 257061,China
  • Received: Revised: Online: Published:
  • Contact: Liu Yunqi
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Novel catalytic performance and selectivity from nano-size zeolites with high exterior surface area and shorter pore pathway have aroused great interest in catalysis field. The progress in control-synthesis strategy and catalysis application of nano-size zeolite or zeolite nanocrystal suspension, especially in self-assemble and nano-composite materials is summarized . The research opportunity based on the industry catalysis and catalytic application prospect in the future are analysed.
Key words: zeolite nano-cryslalline, catalysis, self-assemble, nano-composite

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[ 1 ] 张维萍(Zhang W P) , 韩秀文(Han X W) , 包信和(Bao X H) . 分子催化(China Journal of Molecular Catalysis) , 1999 , 13(5) : 393 —400
[ 2 ] 余润兰(Yu R L) , 邝代治( Kuang D Z) , 邓戊有(Deng W Y) , 王建伟(Wang J W) . 衡阳师范学院学报(自然科学)(Journal of Hengyang Normal College , Natural Science ) , 2001 ,22(6) : 24 —27
[ 3 ] 徐如人(Xu R R) , 庞文琴(Pang W Q) . 无机合成和制备化学( Chemistry of Inorganic Synthesis and Preparation) . 北京(Beijing) : 高等教育出版社( Higher Edu. Press) , 2001.420 —423
[ 4 ] 马跃龙(Ma Y L) , 陈诵英(Chen S Y) , 彭少逸(Peng S Y) .催化学报(Chinese Journal of Catalysis) , 1995 , 16 (5) : 410 —414
[ 5 ] Holmberg B A , Wang H T , Norbeck J M, Yan Y H. Microporous and Mesoporous Materials , 2003 , 59 : 13 —28
[ 6 ] Schoeman B J , Sterte J , Otterstedt J E. Zeolites , 1994 , 14 :110 —116
[ 7 ] Brar T , France P , Smirniotis P G. Industrial & Engineering Chemistry Research , 2001 , 40 : 1133 —1139
[ 8 ] Kirschhock C E , Ravishankar A R , Jacobs P A , Martens J .Journal of Physical Chemistry B , 1999 , 103 : 11021 —11027
[ 9 ] Mintova S , Valtchev V , Bein T. Colloids and Surfaces A:Physicochemical Engineering Aspects , 2003 , 217 : 153 —157
[10] Lassinantti M, Hedlund J , Sterte J . Microporous and Mesoporous Materials , 2000 , 38 : 25 —34
[11] Mintova S , Valtchev V. Microporous and Mesoporous Materials ,2002 , 55 : 171 —179
[12] Mintova S , Petkov N , Karaghiosoff K, Bein T. Materials Science and Engineering , 2002 , 19 : 111 —114
[13] Reding G, Meaurer T , Kraushaar-Czarnetzki B. Microporous and Mesoporous Materials , 2003 , 57 : 83 —92
[14] Persson A E , Schoeman B J , Sterte J , Otterstedt J E. Zeolites ,1995 , 15 :611 —619
[15] Schoeman B J , Sterte J , Otierstedt J E. Journal of Colloids and Interface Science , 1995 , 170 : 449 —456
[16] Dong J P , Zou J , Long Y C. Microporous and Mesoporous Materials , 2003 , 57 : 9 —19
[17] Corkery R W, Ninham B W. Zeolites , 1997 ,18 : 379 —386
[18] Kragten D D , Fedeyko J M, Sawant K R , et al . Journal Physical Chemistry B , 2003 , 107 : 10006 —10016
[19] Zhu G S , Qiu S L , Yu J H , et al . Chemistry of Materials , 1998 ,10 : 1483 —1486
[20] Li Q H , Creaser D , Sterte J . Chemistry of Materials , 2002 , 14 :1319 —1324
[21] Li Q H , Mihailova B , Creaser D , Sterte J . Microporous and Mesoporous Materials , 2001 , 43 : 51 —59
[22] Mintova S , Petkov N , Karaghioso K, et al . Microporous and Mesoporous Materials , 2001 , 50 : 121 —128
[23] Kirschhock C E , Ravishankar R , Looveren L V , et al . Journal Phyical Chemistry B , 1999 , 103 : 4972 —4978
[24] 阎子峰(Yan Z F) . 纳米催化技术( The Technology of Nano-Catalysis) . 北京( Beijing) : 化学工业出版社( Chemical Industry Press) , 2003. 191 —202
[25] Sato K, Nishimura Y, Honna K, et al . Journal of Catalysis ,2001 , 200 : 288 —297
[26] Zhan B Z , White M A , Lumsden M, et al . Chemistry of Materials , 2002 , 14 : 3636 —3642
[27] 蒋茂修(Jiang M X) , 左丽华(Zuo L H) . 工业催化( Industrial Catalysis) , 2003 , 11 (3) : 43 —48
[28] Botella P , Corma A , Lopez-Nieto J M, et al . Journal of Catalysis ,2000 , 195 : 161 —168
[29] Landau M V , Vradman L , Valtchev V , et al . Industrial & Engineering Chemistry Research , 2003 , 42 : 2773 —2782
[30] Camblor M A , Corma A , Martynez A , et al . Journal of Catalysis ,1998 , 179 : 537 —547
[31] Rajagopalan K, Peters A W, Edwards G C. Applied Catalysis ,1986 , 23 (1) : 69 —80
[32] 王学勤(Wang X Q) , 王祥生(Wang X S) . 石油学报(石油加工) (Acta Petrolei Sinica , Petroleum Processing Section) ,1994 , 10 (2) : 38 —43
[33] Yamamura M, Chaki K, Wakatsuki T , et al . Zeolites , 1994 , 14(6) : 643 —649
[34] Sugimoto M, Katsuno H , Takatsu K, et al . Zeolites , 1987 , 7(6) : 503 —507
[35] Schwart S , Corbin D R , Sonnichsen G C. Microporous & Mesoporous Materials , 1998 , 22 (1/3) : 409 —418
[36] Arribas M A , Martinez A. Catalysis Today , 2001 , 65 : 117 —122
[37] Lin J C , Dipre J T , Yates M Z. Chemistry of Materials , 2003 ,15 : 2764 —2773
[38] Takata Y, Tsuru T , Yoshioka T. Microporous and Mesoporous Materials , 2002 , 54 : 257 —268
[39] Mintova S , Bein T. Microporous and MesoporousMaterials , 2001 ,50 : 159 —166
[40] Biz S , Occelli M L. Catalysis Review , Science & Engineering ,1998 , 40 (3) : 329 —407
[41] Smirniotis P G, Davydov L. Catalysis Review , Science & Engineering , 1999 , 41 (1) : 43 —113
[42] Xomeritakis G, Nair S , Tsapatsis M. Microporous and Mesoporous Materials , 2000 , 38 : 61 —73
[43] Clet G, Jansen J C , Bekkum H V. Chemistry of Materials , 1999 ,11 : 1696 —1702
[44] Landau M V , Tavor D , Regev O , et al . Chemistry of Materials ,1999 , 11 : 2030 —2037
[45] Wang H T , Holmberg B A , Yan Y S. Journal of American Chemical Society , 2003 , 125 : 9928 —9929
[46] Prokesova P , Mintov S , Cejka J , et al . Microporous and Mesoporous Materials , 2003 , 64 : 165 —174
[47] Liu Y, Zhang W, Pinnavaia J . Journal of American Chemical Society , 2000 , 122 (36) : 8791 —8802
[48] 韩宇( Han Y) , 肖丰收(Xiao F S) . 催化学报( Chinese Journal of Catalysis) , 2003 , 24(2) : 149 —158
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