中文
Earlier issues
Announcement
More
Progress in Chemistry 2009, Vol. 21 Issue (09): 1734-1741 Previous Articles   Next Articles

• Review •

Bismuth Oxyhalide Compounds as Photocatalysts

Wei Pingyu;   Yang Qinglin** ;  Guo Lin   

  1. (School of Chemistry and Environment, Beijing University of Aeronautics and Astronautics, 100191 Beijing, China)
  • Received: Revised: Online: Published:
  • Contact: Yang Qinglin E-mail:yangql@buaa.edu.cn
PDF ( 5182 ) Cited
Export

EndNote

Ris

BibTeX

Bismuth Oxyhalide Compounds, BiOX (X=Cl, Br, I) are new types of photocatalysts. They exhibit excellent photocatalytic properties due to layered crystal structure and suitable band gaps. In this paper, main preparation methods, morphologies, sizes and photocatalytic activities of micro-nanometer bismuth oxyhalides are reviewed. Bismuth oxyhalide compounds show better photocatalytic activities than TiO2 (P25). With the increasing of X atomic numbers, photocatalytic activities of BiOX are enhanced in sequence. Moreover, the stabilities of BiOX are high. Photocatalytic activities of bismuth oxyhalide compounds are improved by doping and modifications. By designing of the crystal structures and energy band gaps, highly efficient photocatalysts of bismuth oxyhalide compounds can be obtained. At last, the trend of research is prospected.

Contents
1 Introduction
2 Structure of BiOX (X=Cl, Br, I)
3 Preparation methods and morphologies of BiOX (X=Cl, Br, I)
3.1 Preparation methods
3.2 Morphologies of products
4 Photocatalytic activities of BiOX (X=Cl, Br, I)
4.1 BiOCl photocatalyst
4.2 BiOBr and BiOI photocatalysts
4.3 Other Bi based oxyhalides
5 Conclusion

Key words: bismuth oxyhalides, photocatalyst, preparation, photocatalytic activity

CLC Number: 

[ 1 ]  Fujishima A , Honda K. Nature , 1972 , 238 : 37 —38
[ 2 ]  O’regan B , Gratzel M. Nature , 1991 , 353 : 737 —740
[ 3 ]  Hoffmann M R , Martin S T, Choi W, et al . Chem. Rev. , 1995 ,95 : 69 —96
[ 4 ]  Mills A , Hunte S L. J . Photochem. Photobiol . A: Chem. , 1997 ,108 : 1 —35
[ 5 ]  Fujishima A , Hashimoto K, Watanabe T. TiO2 Photocatalysis Fundamentals and Applications. Tokyo : BKC Inc. , 1999
[ 6 ]  Carp O , Huisman C L , Reller A. Prog. Solid State Chem. , 2004 ,32 : 33 —177
[ 7 ]  Choi W, Termin A , Hoffmann M R. J . Phys. Chem. , 1994 , 98 :13669 —13679
[ 8 ]  Asahi R , Morikawa T, Ohwaki T, et al . Science , 2001 , 293 :269 —271
[ 9 ]  Khan S U M, Al-Shahry M I J , William B. Science , 2002 , 297 :2243 —2245
[10 ]  Kudo A , Kato H , Nakagawa S. J . Phys. Chem. B , 2000 , 104 :571 —575
[11 ]  Hwang D W, Kim H G, KimJ , et al . J . Catal . , 2000 , 193 : 40 —48
[12 ]  Hoertz P G, Mallouk T E. Inorg. Chem. , 2005 , 44 : 6828 —6840
[13 ]  Machida M, Mitsuyama T, Ikeue K. J . Phys. Chem. B , 2005 ,109 : 7801 —7806
[14 ]  Zou Z G, Ye J H , Sayama K, et al . Nature , 2001 , 414 : 625 —627
[15 ]  Xu X H , Wang M, Hou Y, et al . J . Mater. Sci . Lett . , 2002 , 21 :1655 —1656
[16 ]  Rengaraj S , Li X Z, Tanner P A , et al . J . Mol . Catal . A2Chem. ,2006 , 247 : 36 —43
[17 ]  Gurunathan K. Int . J . Hydrogen Energy , 2004 , 29 : 933 —940
[18 ]  Kako T, Zou Z G, Katagiri M, et al . Chem. Mater. , 2007 , 19 :198 —202
[19 ]  Tang J W, Zou Z G, Ye J H , et al . J . Phys. Chem. C , 2007 ,111 : 12779 —12785
[20 ]  Yu J G, Xiong J F , Cheng B , et al . J . Solid State Chem. , 2005 ,178 : 1968 —1972
[21 ]  Shimodaira Y, Kato H , Kobayashi H , et al . J . Phys. Chem. B ,2006 , 110 : 17790 —17797
[22 ]  Zou Z G, Ye J H , Arakawa H. Chem. Mater. , 2001 , 13 : 1765 —1769
[23 ]  Muktha B , Priya M H , Madras G, et al . J . Phys. Chem. B , 2005 ,109 : 11442 —11449
[24 ]  钱逸泰(Qian Y T) . 结晶化学导论( Introduction of Crystal Chemistry) . 合肥: 中国科学技术大学出版社( Hefei: China Science and Technology University Press) , 2005. 348 —352
[25 ]  Kijima N , Matano K, Saito M, et al . Appl . Catal . A2Gen. , 2000 ,206 : 237 —244
[26 ]  Perera S , Zelenski N A , Pho R E , et al . J . Solid State Chem. ,2007 , 180 : 2916 —2925
[27 ]  Huang W L , Zhu Q S. Comput . Mater. Sci . , 2008 , 43 : 1101 —1108
[28 ]  Zhang K L , Liu C M, Huang F Q , et al . Appl . Catal . B2Environ. ,2006 , 68 : 125 —129
[29 ]  Liu A R , Wang S M, Zhao Y R , et al . Mater. Chem. Phys. ,2006 , 99 : 131 —134
[30 ]  Kim S J , Lee E G, Park S D , et al . J . Sol-Gel Sci . Technol . ,2001 , 22 : 63 —74
[31 ]  Anpo M, Shima T, Kodama S , et al . J . Phys. Chem. , 1987 , 91 :4305 —4310
[32 ]  王云燕(Wang Y Y) , 彭文杰(Peng WJ ) , 柴立元(Chai L Y) 等.湖南冶金(Hunan Metallurgy) , 2003 , 31 (3) : 20 —23
[33 ]  Daminova T V , Novokreshchenova M N , Yukhin Y M. Russ. J .Appl . Chem. , 2005 , 78 (12) : 1948 —1952
[34 ]  Dellinger T M, Braun P V. Scripta. Mater. , 2001 , 44 : 1893 —1897
[35 ]  Cao C B , Lv R T, Zhu H S. J . Metastable Nanocryst . Mater. ,2005 , 23 : 79 —82
[36 ]  Henle J , Simon P , Frenzel A , et al . Chem. Mater. , 2007 , 19 :366 —373
[37 ]  Wang W D , Huang F Q , Lin X P. Scripta Mater. , 2007 , 56 :669 —672
[38 ]  Deng H , Wang J W, Peng Q , et al . Chem. Eur. J . , 2005 , 11 :6519 —6524
[39 ]  Zhang X, Ai Z H , Jia F L , et al . J . Phys. Chem. C , 2008 , 112 :747 —753
[40 ]  Zhou S X, Ke Y X, Li J M, et al . Mater. Lett . , 2003 , 57 : 2053 —2055
[41 ]  Zhu L Y, Xie Y, Zheng X W, et al . Inorg. Chem. , 2002 , 41 :4560 —4566
[42 ]  Chen X Y, Huh H S , Lee S W. J . Solid State Chem. , 2007 , 180 :2510 —2516
[43 ]  Geng J , Hou W H , Lv Y N , et al . Inorg. Chem. , 2005 , 44 :8503 —8509
[44 ]  Wang C H , Shao C L , Liu Y C , et al . Scripta Mater. , 2008 , 59 :332 —335
[45 ]  Lin X P , Shan Z C , Li K Q , et al . Solid State Sci . , 2007 , 9 :944 —949
[46 ]  Lin X P , Huang T, Huang F Q , et al . J . Phys. Chem. B , 2006 ,110 : 24629 —24634
[47 ]  车玉萍( Che Y P) . 北京航空航天大学硕士论文(Master Dissertation of Beihang University) , 2007
[48 ]  安惠中(An H Z) . 北京航空航天大学博士论文(Doctor Dissertation of Beihang University) , 2007
[49 ]  Pekakis P A , Xekoukoulotakis N P , Mantzavinos D. Water Res. ,2006 , 40 : 1276 —1286
[50 ]  Yang H M, Ouyang J , Tang A D , et al . Mater. Res. Bull . , 2006 ,41 : 1310 —1318
[51 ]  Chen F , Xie Y D , Zhao J C , et al . Chemosphere , 2001 , 44 :1159 —1168
[52 ]  Jung S C , Kim S J , Imaishi N , et al . Appl . Catal . B2Environ. ,2005 , 55 : 253 —257
[53 ]  Liu Z Y, Sun D D , Guo P , et al . Nano Lett . , 2007 , 7 : 1081 —1085
[54 ]  ImJ S , Kim M I , Lee Y S. Mater. Lett . , 2008 , 62 : 3652 —3655
[55 ]  Wang WD , Huang F Q , Lin X P , et al . Catal . Commun. , 2008 ,9 : 8 —12
[56 ]  Shan Z C , Wang W D , Lin X P , et al . J . Solid State Chem. ,2008 , 181 : 1361 —1366
[57 ]  Lin X P , Huang F Q , Wang W D , et al . Appl . Catal . A-Gen. ,2006 , 307 : 257 —262
[58 ]  Yao W F , Xu X H , Wang H , et al . Appl . Catal . B-Environ. ,2004 , 52 : 109 —116
[1] Dandan Wang, Zhaoxin Lin, Huijie Gu, Yunhui Li, Hongji Li, Jing Shao. Modification and Application of Bi2MoO6 in Photocatalytic Technology [J]. Progress in Chemistry, 2023, 35(4): 606-619.
[2] Xuan Li, Jiongpeng Huang, Yifan Zhang, Lei Shi. 1D Nanoribbons of 2D Materials [J]. Progress in Chemistry, 2023, 35(1): 88-104.
[3] Yuexiang Zhu, Weiyue Zhao, Chaozhong Li, Shijun Liao. Pt-Based Intermetallic Compounds and Their Applications in Cathodic Oxygen Reduction Reaction of Proton Exchange Membrane Fuel Cell [J]. Progress in Chemistry, 2022, 34(6): 1337-1347.
[4] Caiwei Wang, Dongjie Yang, Xueqing Qiu, Wenli Zhang. Applications of Lignin-Derived Porous Carbons for Electrochemical Energy Storage [J]. Progress in Chemistry, 2022, 34(2): 285-300.
[5] Xiangkang Cao, Xiaoguang Sun, Guangyi Cai, Zehua Dong. Durable Superhydrophobic Surfaces: Theoretical Models, Preparation Strategies, and Evaluation Methods [J]. Progress in Chemistry, 2021, 33(9): 1525-1537.
[6] Zhen Zhang, Shuang Zhao, Guobing Chen, Kunfeng Li, Zhifang Fei, Zichun Yang. Preparation and Applications of Silicon Carbide Monolithic Aerogels [J]. Progress in Chemistry, 2021, 33(9): 1511-1524.
[7] Jinzhao Li, Zheng Li, Xupin Zhuang, Jixian Gong, Qiujin Li, Jianfei Zhang. Preparation of Cellulose Nanocrystallines and Their Applications in CompositeMaterials [J]. Progress in Chemistry, 2021, 33(8): 1293-1310.
[8] Lizhong Chen, Qiaobin Gong, Zhe Chen. Preparation and Application of Ultra-Thin Two Dimensional MOF Nanomaterials [J]. Progress in Chemistry, 2021, 33(8): 1280-1292.
[9] Xiaoxiao Xiang, Xiaowen Tian, Huie Liu, Shuang Chen, Yanan Zhu, Yuqin Bo. Controlled Preparation of Graphene-Based Aerogel Beads [J]. Progress in Chemistry, 2021, 33(7): 1092-1099.
[10] Ying Yang, Shupeng Ma, Yuan Luo, Feiyu Lin, Liu Zhu, Xueyi Guo. Multidimensional CsPbX3 Inorganic Perovskite Materials: Synthesis and Solar Cells Application [J]. Progress in Chemistry, 2021, 33(5): 779-801.
[11] Ying Yang, Yuan Luo, Shupeng Ma, Congtan Zhu, Liu Zhu, Xueyi Guo. Advances of Electron Transport Materials in Perovskite Solar Cells: Synthesis and Application [J]. Progress in Chemistry, 2021, 33(2): 281-302.
[12] Ying Geng, Mohe Zhang, Jin Fu, Ruisha Zhou, Jiangfeng Song. MOF-74 and Its Compound: Diverse Synthesis and Broad Application [J]. Progress in Chemistry, 2021, 33(12): 2283-2307.
[13] Wen Zhou, Xin Zhang, Hongpeng Ma, Jie Xu, Bin Guo, Panxin Li. Chemical and Physical Mechanism and Method of Preparation of Thermoplastic Starch [J]. Progress in Chemistry, 2021, 33(11): 1972-1982.
[14] Runtian Wang, Chunli Liu, Zhenbin Chen. Imprinted Composite Membranes [J]. Progress in Chemistry, 2020, 32(7): 989-1002.
[15] Jianlei Qi, Qinqin Xu, Jianfei Sun, Dan Zhou, Jianzhong Yin. Synthesis, Characterization and Analysis of Graphene-Supported Single-Atom Catalysts [J]. Progress in Chemistry, 2020, 32(5): 505-518.