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Progress in Chemistry 2005, Vol. 17 Issue (04): 614-621 Previous Articles   Next Articles

• Review •

Preparation and Application of Amorphous Alloy Catalyst

Xiong Zhongqiang;Mi Zhentao;Zhang Xiangwen*   

  1. Key Laboratory for Green Chemical Technology, School of Chemical Engineering & Technology, Tianjin University,Tinajin 300072,China
  • Received: Revised: Online: Published:
  • Contact: Zhang Xiangwen
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The development and applications of amorphous alloy catalyst are summarized. The most widely used techniques for the preparation of amorphous alloy catalyst are classified into rapid quenching method, chemical reduction method and impregnation-chemical reduction method. The reaction activity of the catalyst can be adjusted by changing the preparing condition, which including the calcination temperature, the metal load and the carrier. The amorphous structure, surface morphology and activity center can be determined and characterized by XRD, EXAFS, DSC, SEM, TEM and XPS. A detailed discussion of amorphous alloy catalyst in hydrogenation of unsaturated compound is presented.
Key words: amorphous alloys, catalysts, rapid quenching methods, chemical reduction methods

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[ 1 ] Smith G V , Brower W E. Proc. Int . Congr. Catal . 7th , Tokyo ,1980. 355
[ 2 ] 唐忠( Tang Z) . 化工进展(Chemical Industry and Engineering Progress) , 2001(2) : 24 —30
[ 3 ] 吕志果(Lv Z G) , 郭振美( Guo Z M) . 化工进展(Chemical Industry and Engineering Progress) , 2002 , 21(8) : 552 —555
[ 4 ] 唐忠( Tang Z) . 精细石油化工进展(Advances in Fine Petrochemicals) , 2000 , 1(2) : 23 —27
[ 5 ] 闵恩泽(Min E Z) , 李成岳(Li C Y) . 绿色石化技术的科学与工程基础( Science and Engineering Foundation of Green Petrochemical Technology) . 北京(Beijing) : 中国石化出版社(China Petrochemical Press) , 2002
[ 6 ] Duwez P , Willens R H. TMS-AIME , 1963 , 227 : 362
[ 7 ] Deng J F , Li H X, Wang W J . Catalysis Today , 1999 , 51 :113 —125
[ 8 ] 宗保宁(Zong B N) , 闵恩泽(Min E Z) , 朱永山(Zhu Y S) .CN 91 111 807. 1 , 1993
[ 9 ] Ma A Z , Lu W Z , Zong B N , et al . Research in Chinese Univ. ,2000 , 16 : 15
[10] Li H X, Li H , Dai WL , et al . Applied Catalysis A: General ,2003 , 238 : 119 —130
[11] 马爱增(Ma A Z) . 催化学报(Chinese Journal of Catalysis) ,1999 , 20(6) : 603 —607
[12] 杨军(Yang J) , 柴亮(Chai L) , 邓景发(Deng J F) 等. 化学学报(Acta China Sinica) , 1994 , 52 : 53 —58
[13] Deng J F , Zhang X P , Min E Z. Applied Catalysis , 1988 , 37 :339 —343
[14] Li H X, Wang W J , Zong B N , et al . Chem. Lett . , 1998 , 4 :371 —372
[15] Deng J F , Zhang X P. Applied Catalysis A: General , 1988 , 37 :339 —343
[16] Deng J F , Zhang X P. Solid State Ionics , 1989 , 32 : 1006 —1011
[17] 邓景发(Deng J F) , 张西平(Zhang X P) , 刘定江(Li D J ) 等.化学学报(Acta Chimica Sinica) , 1991 , 49(3) : 209 —213
[18] Wang H M, Yu Z B , Chen H Y, et al . Applied Catalysis A:General , 1995 , 129 : L143 —L149
[19] Yu Z B , Qiao M H , Li H X, et al . Applied Catalysis A:General , 1997 , 163 : 1 —13
[20] Zhang R B , Li F Y, Zhang N , et al . Applied Catalysis A:General , 2003 , 239 : 17 —23
[21] 石秋杰(Shi Q J) , 李凤仪(Li F Y) , 罗来涛(Luo L T) . 分子催化(Journal of Molecular Catalysis) , 1999 , 13(1) : 9 —14
[22] Baiker A. Journal of Molecular Catalysis A: Chemical , 1997 ,115 : 473 —493
[23] Takahashi T , Inoue M, Kai T. Applied Catalysis A: General ,2001 , 218 : 189 —195
[24] Takahashi T , Kai T. Materials Science and Engineering , 1999 ,A267 : 207 —213
[25] Yu X B , Wang M H , Li H X. Applied Catalysis A: General ,2000 , 202 : 17 —22
[26] Li H , Li H X, Dai WL , et al . Applied Catalysis A: General ,2001 , 207 : 151 —157
[27] 韦世强(Wei S Q) , 王晓光(Wang X G) , 殷士龙(Yin SL) 等.催化学报(Chinese Journal of Catalysis) , 2001 , 22 (2) : 113 —118
[28] 王晓光(Wang X G) , 张新夷(Zhang X Y) , 李忠瑞(Li Z R)等. 催化学报(Chinese Journal of Catalysis) , 2001 , 22 (4) :397 —401
[29] Li H X, Chen H Y, Dong S Z , et al . Applied Surface Science ,1998 , 125 : 115 —119
[30] Deng J F , Chen H Y, Bao X H , et al . Applied Surface Science ,1994 , 81 : 341 —346
[31] 沈百荣(Shen B R) , 方志刚( Fang Z G) , 范康年( Fan K N)等. 化学学报(Acta Chimica Sinica) , 1999 , 57 : 366 —371
[32] Okamoto Y, Nitta Y, Imanaka T , et al . J . Catal . , 1980 , 64 :397 —404
[33] Hou Y J , Wang Y Q , He F , et al . Materials Letters , 2004 , 58 :1267 —1271
[34] Hou Y J , Wang Y Q , He F , et al . Applied Catslysis A: General ,2004 , 259 : 35 —40
[35] Beilin E , Traverse A , Szasz A , et al . J . Phys. F : Met . Phys. ,1987 , 17 : 1913 —1923
[36] Tamaki J , Imanaka T. Chem. Lett . , 1986 : 679 —682
[37] Li H X, Xu Y P , Deng J F. New J . Chem. , 1999 , 23 (11) :1059 —1061
[38] Yu X B , Li H X, Deng J F. Applied Catalysis A: General ,2000 , 199 : 191 —198
[39] Wang W J , Qiao M H , Yang J , et al . Applied Catalysis A:General , 1997 , 163 (1/2) : 101 —109
[40] Wang W J , Qiao M H , Li H X, et al . J . Chem. Tech.Biotech. , 1998 , 72(3) : 280 —284
[41] Li H , Li H X, Wang WJ , et al . Chem. Lett . , 1999 , 7 : 629 —630
[42] 乔明华(Qiao M H) , 谢颂海(Xie S H) , 戴维林(Dai WL) 等.化学学报(Acta Chimica Sinica) , 2000 , 58(7) : 904 —908
[43] Wang W J , Qiao M H , Li H X, et al . Applied Catalysis A:General , 1998 , 166 : L243 —L247
[44] Wang W J , Qiao M H , Li H X, et al . Applied Catalysis A:General , 1998 , 168 : 151 —157
[45] Wang W J , Li H X, Xie S H , et al . Applied Catalysis A:General , 1999 , 184 : 33 —39
[46] Wang W J , Li H , Li H X, et al . Applied Catalysis A: General ,2000 , 203 : 301 —306
[47] Wang W J , Li H X, Deng J F. Applied Catalysis A: General ,2000 , 203 : 293 —300
[48] 陈海鹰(Chen H Y) , 邓景发(Deng J F) , 盛世善(Sheng S S)等. 化学学报(Acta Chimica Sinica) , 1994 , 52 : 877 —882
[49] Varga M, Mulas G, Cocco G, et al . Materials Science and Engineering , 2001 , A304P306 : 462 —466
[50] 宋真(Song Z) , 郝志显(Hao Z X) , 谭大力(Tan D L) 等. 催化学报(Chinese Journal of Catalysis) , 1999 , 20(3) : 193 —198
[51] 马爱增(Ma A Z) , 陆婉珍(Lu W Z) , 闵恩泽(Min E Z) . 石油化工(Petrochemical Technology) , 2000 , 29(3) : 179 —183
[52] Guo H B , Li H X, Zhu J , et al . Journal of Molecular Catalysis A: Chemical , 2003 , 200 : 213 —221
[53] Guo H B , Li H X, Xu Y P , et al . Materials Letters , 2002 , 57 :392 —398
[54] Chen X F , Li H X, Luo H S , et al . Applied Catalysis A:General , 2002 , 233 : 13 —20
[55] Li H X, Wu Y D , Luo H S , et al . Journal of Catalysis , 2003 ,214 : 15 —25
[56] Li H , Li H X, Deng J F. Applied Catalysis A: General , 2000 ,193 : 9 —15
[57] Xie S H , Li H X, Li H , et al . Applied Catalysis A: General ,1999 , 189 : 45 —52
[58] 余锡宾(Yu X B) , 王明辉(Wang M H) , 叶林美(Ye L M) 等.分子催化(Journal of Molecular Catalysis) , 1999 , 13(1) : 3 —8
[59] 余锡宾(Yu X B) , 王桂华(Wang G H) , 李和兴(Li H X) . 分子催化(Journal of Molecular Catalysis) , 1999 , 13 (5) : 351 —356
[60] 程庆彦(Cheng Q Y) , 李伟(Li W) , 张明慧(Zhang M H) 等.催化学报(Chinese Journal of Catalysis) , 2001 , 22 (4) : 326 —330
[61] 陈昌荣(Chen C R) , 姜明(Jiang M) , 万小红(Wan X H) 等.催化学报(Chinese Journal of Catalysis) , 1999 , 20 (6) : 659 —663
[62] 李江(Li J) , 乔明华(Qiao M H) , 邓景发(Deng J F) . 高等学校化学学报(Chemical Journal of Chinese Universities) , 2001 ,22(6) : 1022 —1024
[63] Xie S H , Qiao M H , Li H X, et al . Applied Catalysis A:General , 1999 , 176 : 129 —134
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