中文
Earlier issues
Announcement
More
Progress in Chemistry 2006, Vol. 18 Issue (11): 1482-1488 Previous Articles   Next Articles

• Review •

The Research Progress of Mesoporous Alumina

Chuanrun Li;Yisi Feng*;Qinghua Yang   

  1. School of Chemical Engineering, Hefei University of Technology, Hefei 230029, China
  • Received: Revised: Online: Published:
  • Contact: Yisi Feng
PDF ( 3091 ) Cited
Export

EndNote

Ris

BibTeX

Surface areas exceeding 350m2/g,pore sizes ranging from 2 to 50nm and with a narrow pore size distribution are characteristics of mesoporous alumina(MA). The new kind of lacunaris alumina shows a certain potential in catalysis, and appears very challenging for material application. Recent advances in the field of mesoporous alumina is reviewed with 64 references. Various synthesis approaches including neutral, anionic and cationic toutes, characterization of structure by various experimental techniques including XRD,N2-sorption isotherms,TEM and 27Al MAS NMR, and their applications in catalysis and adsorption are discussed in detail. The development trend in this field is also elucidated.

Key words: mesoporous alumina, synthesis, catalysis, adsorption

CLC Number: 

[ 1 ] 杨重愚(Yang Z Y) . 氧化铝生产工艺学(第二版) (Technology of Alumina Production , 2nd ed. ) . 北京: 冶金工业出版社(Beijing : Metallurgical Industry Press) ,1993. 6 —12
[ 2 ] Zhou R S , Snyder R L. Acta Cryst . B , 1991 , 47 : 617 —630
[ 3 ] 徐如人(Xu R R) , 庞文琴(Pang W Q) . 分子筛与多孔材料化学(Chemistry2Zeolites and Porous Materials) . 北京: 科学出版社(Beijing : Science Press) , 2004. 145 —155
[ 4 ] Cejka J . Appl . Catal . A-General , 2003 , 254 : 327 —339
[ 5 ] Bagshaw S A , Prouzet E , Pinnavaia T J . Science , 1995 , 269 :1242 —1245
[ 6 ] Bagshaw S A , Pinnavaia T J . Angew. Chem. Int . Ed. Engl . ,1996 , 35 : 1102 —1105
[ 7 ] Horvath G, Kawazoe J . J . Chem. Eng. Jpn. , 1983 , 16 : 470 —475
[ 8 ] Barrett E P , Joyner L G, Halender P P. J . Am. Chem. Soc. ,1951 , 73 : 373 —380
[ 9 ] Zhang W, Pinnavaia T J . Chem. Commun. , 1998 , 11 : 1185 —1186
[10] Luo Q , Li L , Xue Z , Zhao D. Nanoporous Materials Ⅱ, Studies in Surface Science and Catalysis ( eds. Sayari A , Jaroniec M,Pinnavaia TJ ) . Amsterdam: Elsevier , 2000 , 129 : 37 —42
[11] Deng W, Bodart P , Pruski M, et al . Microp. Mesop. Mater. ,2002 , 52 : 169 —177
[12] González-Pena V , Márquez-Alvarez C , Sastre E , et al . Impact of Zeolites and Other Porous Materials on the New Technologies at the Beginning of the New Millennium, Studies in Surface Science and Catalysis ( eds. Aiello R , Giordano G, Testa F) . Amsterdam:Elsevier , 2002 , 142 : 1283 —1289
[13] Diaz I , Gonzalez-Pena V , Marquez-Alvarez C , et al . Coll .Czech. Chem. Commun. , 2003 , 68 : 1937 —1948
[14] Gonzalez-Pena V , Marquez-Alvarez C , Diaz I , et al . Microp.Mesop. Mater. , 2005 , 80 : 173 —182
[15] González-Pena V , Diaz I , Márquez-Alvarez C , et al . Microp.Mesop. Mater. , 2001 , 203 : 44 —45
[16] Yang P D , Zhao D Y, Margolese D I , et al . Chem. Mater. ,1999 , 11 : 2813 —2826
[17] Niesz K, Yang P D , Somorjai G A. Chem. Commun. , 2005 ,1986 —1987
[18] Vaudry F , Khodabandeh S , Davis M E. Chem. Mater. , 1996 ,8 : 1451 —1464
[19] Kim C , Kim Y, Kim P , et al . Korean Journal of Chemical Engineering , 2003 , 20 : 1142 —1144
[20] Cejka J , O ilkováN , Rathousk? J , et al . Phys. Chem. Chem.Phys. , 2001 , 3 : 5076 —5081
[21] Cejka J , VeseláL , Rathousk? J , et al . Nanoporous Materials Ⅲ,Studies in Surface Science and Catalysis (eds. Sayari A , Jaroniec M) . Amsterdam: Elsevier , 2002 , 141 : 429 —436
[22] Kim Y, Kim P , Kim C , et al . Korean Journal of Chemical Engineering , 2005 , 22 : 321 —327
[23] Yada M, Kitamura H , Machida M, et al . Langmuir , 1997 , 13 :5252 —5257
[24] Yada M, Hiyoshi H , Ohe K, et al . Inorg. Chem. , 1997 , 36 :5565 —5569
[25] Yada M, Machida M, Kijima T. Chem. Commun. , 1996 , 769 —770
[26] Sicard L , Frasch J , Soulard M, et al . Microp. Mesop. Mater. ,2002 , 25 : 44 —45
[27] Sicard L , Lebeau B , Patarin J , et al . Langmuir , 2002 , 18 : 74 —82
[28] Valange S , Guth J L , Kolenda F , et al . Microp. Mesop. Mater. ,2000 , 35/36 : 597 —607
[29] Caragheorgheopol A , Caldararu H , Vasilescu M, et al . J . Phys.Chem. B , 2004 , 108 : 7735 —7743
[30] Cabrera S , Haskouri J , Alamo J , et al . Adv. Mater. , 1999 , 11 :379 —381
[31] Lee H C , Kim H J , Choo D H , et al . Nanotechnology in Mesostructured Materials , Studies in Surface Science and Catalysis (eds. Park S E , Ryoo R , Ahn W S) . Amsterdam: Elsevier ,2003 , 146 : 217 —220
[32] Kim H J , Lee H C , Choo D H , et al . Nanotechnology in Mesostructured Materials , Studies in Surface Science and Catalysis(eds. Park S E , Ryoo R , Ahn W S) . Amsterdam: Elsevier ,2003 , 146 : 213 —216
[33] Cabrera S , Haskouri J E , Guillem C , et al . Solid State Sci . ,2000 , 2 : 405 —420
[34] Zhang X, Zhang F , Chan K Y. Mater. Lett . , 2004 , 58 : 2872 —2877
[35] Liu X, Wei Y, Jin D , et al . Mater. Lett . , 2000 , 42 : 143 —149
[36] Sicard L , Llewellyn P L , Patarin J , et al . Microp. Mesop.Mater. , 2001 , 44/45 : 195 —201
[37] Yada M, Okya M, Machida M, et al . Chem. Commun. , 1998 ,1941 —1942
[38] Yada M, Okya M, Ohe K, et al . Langmuir , 2000 , 16 : 1535 —1541
[39] Yada M, Okya M, Machida M, et al . Langmuir , 2000 , 16 :4752 —4755
[40] Cejka J , Zilkova N , Rathousky J , et al . Langmuir , 2004 , 20 :7532 —7539
[41] Diaz I , Gonzalez-Pena V , Marquez-Alvarez C , et al . Microp.Mesop. Mater. , 2004 , 68 : 11 —19
[42] Valange S , Barrault J , Derouault A , et al . Microp. Mesop.Mater. , 2001 , 44/45 : 211 —220
[43] Valange S , Derouault A , Barrault J , et al . J . Mol . Catal . A Chem. , 2005 , 228 : 255 —266
[44] Zhu Z H , Zhu H Y, Wang S B , et al . Catal . Lett . , 2003 , 91 :73 —81
[45] Kalu?a L , Zdra?il M, O ilková N , et al . Catal . Commun. , 2002 ,3 : 151 —157
[46] Cejka J , OilkováN , Kalu?a L , et al . Nanoporous Materials Ⅲ,Studies in Surface Science and Catalysis (eds. Sayari A , Jaroniec M) . Amsterdam: Elsevier , 2002 , 141 : 243 —250
[47] Onaka M, Oikawa T. Chem. Lett . , 2002 , 31 : 850 —851
[48] Oikawa T , Ookoshi T , Tanaka T , et al . Microp. Mesop. Mater. ,2004 , 74 : 93 —103
[49] Aguado J , Escola J M, Castro M C , et al . Appl . Catal . A-General , 2005 , 284 : 47 —57
[50] Balcar H , Hamtil R , Zilkova N , et al . Catal . Lett . , 2004 , 97 :25 —29
[51] Kim P , Kim Y, Kim H , et al . J . Mol . Catal . A: Chem. , 2005 ,231 : 247 —254
[52] Kim P , Kim Y, Kim C , et al . Catal . Lett . , 2003 , 89 : 185 —192
[53] Kim P , Kim Y, Kim H , et al . J . Mol . Catal . A: Chem. , 2004 ,219 : 87 —95
[54] Seki T , Onaka M. Chem. Lett . , 2005 , 34 : 262 —263
[55] Concepcion P , Navarro M T , Blasco T , et al . Catal . Today ,2004 , 96 : 179 —186
[56] Bronstein L M, Chernyshov D M, Karlinsey R , et al . Chem. Mater. , 2003 , 15 : 2623 —2631
[57] 李奚(Li X) , 杨春(Yang C) . 南京师范大学学报(工程技术版) ( Journal of Nanjing Normal University2Engineering and Technology) , 2002 , 4 : 5 —9
[58] Zhao X P , Yue Y H , Zhang Y, et al . Catal . Lett . , 2003 , 89 :41 —47
[59] Kim Y H , Kim C M, Choi I H , et al . Environ. Sci . Technol . ,2004 , 38 : 924 —931
[60] Ho Y S. Environ. Sci . Technol . , 2004 , 38 : 3214 —3215
[61] Kim Y H , Kim C M, Choi I , et al . Environ. Sci . Technol . ,2004 , 38 : 3216 —3216
[62] Rengaraj S , Kim Y, Joo C K, et al . J . Coll . Inter. Sci . , 2004 ,273 : 14 —21
[63] Marouf-Khelifa K, Khelifa A , Belhakem A , et al . Adsorp. Sci .Technol . , 2004 , 22 : 1 —12
[64] Hovijitra N , Lee S W, Shang H , et al . Chemical and Biological Sensing V(Proc. SPIE) , 2004 , 5416 : 84 —93
[1] Jing He, Jia Chen, Hongdeng Qiu. Synthesis of Traditional Chinese Medicines-Derived Carbon Dots for Bioimaging and Therapeutics [J]. Progress in Chemistry, 2023, 35(5): 655-682.
[2] Jianfeng Yan, Jindong Xu, Ruiying Zhang, Pin Zhou, Yaofeng Yuan, Yuanming Li. Nanocarbon Molecules — the Fascination of Synthetic Chemistry [J]. Progress in Chemistry, 2023, 35(5): 699-708.
[3] Xinyue Wang, Kang Jin. Chemical Synthesis of Peptides and Proteins [J]. Progress in Chemistry, 2023, 35(4): 526-542.
[4] Liu Yvfei, Zhang Mi, Lu Meng, Lan Yaqian. Covalent Organic Frameworks for Photocatalytic CO2 Reduction [J]. Progress in Chemistry, 2023, 35(3): 349-359.
[5] Lan Mingyan, Zhang Xiuwu, Chu Hongyu, Wang Chongchen. MIL-101(Fe) and Its Composites for Catalytic Removal of Pollutants: Synthesis Strategies, Performances and Mechanisms [J]. Progress in Chemistry, 2023, 35(3): 458-474.
[6] Zixuan Liao, Yuhui Wang, Jianping Zheng. Research Advance of Carbon-Dots Based Hydrophilic Room Temperature Phosphorescent Composites [J]. Progress in Chemistry, 2023, 35(2): 263-373.
[7] Kelong Fan, Lizeng Gao, Hui Wei, Bing Jiang, Daji Wang, Ruofei Zhang, Jiuyang He, Xiangqin Meng, Zhuoran Wang, Huizhen Fan, Tao Wen, Demin Duan, Lei Chen, Wei Jiang, Yu Lu, Bing Jiang, Yonghua Wei, Wei Li, Ye Yuan, Haijiao Dong, Lu Zhang, Chaoyi Hong, Zixia Zhang, Miaomiao Cheng, Xin Geng, Tongyang Hou, Yaxin Hou, Jianru Li, Guoheng Tang, Yue Zhao, Hanqing Zhao, Shuai Zhang, Jiaying Xie, Zijun Zhou, Jinsong Ren, Xinglu Huang, Xingfa Gao, Minmin Liang, Yu Zhang, Haiyan Xu, Xiaogang Qu, Xiyun Yan. Nanozymes [J]. Progress in Chemistry, 2023, 35(1): 1-87.
[8] Hao Chen, Xu Xu, Chaonan Jiao, Hao Yang, Jing Wang, Yinxian Peng. Fabrication of Multifunctional Core-Shell Structured Nanoreactors and Their Catalytic Performances [J]. Progress in Chemistry, 2022, 34(9): 1911-1934.
[9] Dang Zhang, Xi Wang, Lei Wang. Biomedical Applications of Enzyme-Powered Micro/Nanomotors [J]. Progress in Chemistry, 2022, 34(9): 2035-2050.
[10] Bowen Xia, Bin Zhu, Jing Liu, Chunlin Chen, Jian Zhang. Synthesis of 2,5-Furandicarboxylic Acid by the Electrocatalytic Oxidation [J]. Progress in Chemistry, 2022, 34(8): 1661-1677.
[11] Huiyue Wang, Xin Hu, Yujing Hu, Ning Zhu, Kai Guo. Enzyme-Catalyzed Atom Transfer Radical Polymerization [J]. Progress in Chemistry, 2022, 34(8): 1796-1808.
[12] Yehjun Lim, Yanmei Li. Chemical Synthesis/Semisynthesis of Post-Translational Modified Tau Protein [J]. Progress in Chemistry, 2022, 34(8): 1645-1660.
[13] Yiling Tan, Shichun Li, Xi Yang, Bo Jin, Jie Sun. Strategies of Improving Anti-Humidity Performance for Metal Oxide Semiconductors Gas-Sensitive Materials [J]. Progress in Chemistry, 2022, 34(8): 1784-1795.
[14] Peng Xu, Biao Yu. Challenges in Chemical Synthesis of Glycans and the Possible Problems Relevant to Condensed Matter Chemistry [J]. Progress in Chemistry, 2022, 34(7): 1548-1553.
[15] Deshan Zhang, Chenho Tung, Lizhu Wu. Artificial Photosynthesis [J]. Progress in Chemistry, 2022, 34(7): 1590-1599.