Research Progress on the Nano-TiO2 Cement-based Photocatalytic Materials
LIANG Chen1,2, WU Yanqing3, WANG Dawei4, WANG Han1,2, LIU Lele1,2, ZHAO Piqi1,2
1 School of Materials Science and Engineering, University of Jinan, Jinan 250022; 2 Shandong Provincial Key Laboratory of Preparation and Measurement of Building Materials, University of Jinan, Jinan 250022; 3 Shandong Huasen Concrete Co., Ltd., Jinan 2500034 Shenzhen Gangchuang Building Material Co., Ltd., Shenzhen 518051
Abstract: Photocatalytic technology is one of the effective approaches to solve the problem of atmospheric pollution. Nano-TiO2, due to its inherent advantages of high catalytic efficiency, good thermal stability, economic and environmental protection, has become the best-received photocatalysis material. In this paper, the photocatalytic mechanism and property of nano-TiO2 were reviewed. And the effect of inherent fators (crystalline structure, composition and particle size) and extrinsic factors (light intensity, tempreture and pH) on photocatalysis were also included. Additio-nally, based on the composite system of nano-TiO2 and cementitious materials, the dispersion of nano-TiO2 in water, effect of nano-TiO2 on the matrix mechanical properties and photocatalytic performance of that composite system were respectively described and summarized. However, the problems and prospects of nano-TiO2 cement-based photocatalytic materials were pointed out to provide reference for the preparation of new nano-TiO2 cement-based photocatalytic materials.
1 佚名.新发现,2016(2),12. 2 王程,施惠生,李艳.化工新型材料,2011,39(4),10. 3 陈萌,金立生,储江伟,等.武汉理工大学学报,2013,35(2),61. 4 刘琴.锰渣制备光催化水泥及其性能研究.硕士学位论文,中南大学,2013. 5 Marco T D, Bottalico L, Manganelli G, et al. In: Photo PAQ Conference 2014 “photocatalysis: Science and Application for Urban Air Quality”. France,2014. 6 Cassar L, Beeldens A, Pimpinelli N, et al. In: International Rilem Symposium on Photocatalysis Environment & Construction Materials.Florence,2007. 7 Pietrzak A, Adamus J, Langier B. Key Engineering Materials,2016,687,243. 8 张金龙,陈锋,田宝柱,等.光催化,华东理工大学出版社,2012. 9 刘春艳.纳米光催化及光催化环境净化材料,化学工业出版社,2008. 10 Brown J D, Williamson D L, Nozik A J. Journal of Physical Chemistry,1985,89(14),3076. 11 方明,高基伟,申乾宏,等.硅酸盐学报,2006,34(4),438. 12 沈杭燕,唐新硕.浙江大学学报,1998(4),55. 13 Sclafani A, Palmisano L, Schiavello M. Journal of Physical Chemistry,1990,94(2),829. 14 Mendoza C, Valle A, Castellote M, et al. Applied Catalysis B Environmental,2014,178,155. 15 李广友.TiO2颗粒尺寸对PI基复合薄膜结构与性能影响的研究.硕士学位论文,哈尔滨理工大学,2015. 16 黄婉霞,孙作凤,吴建春,等.稀有金属,2005,29(1),34. 17 Anpo M, Shima T, Kodama S, et al. Journal of Chemical Physics,1987,91,16. 18 岳林海,水淼,徐铸德.化学学报,1999,57(11),1219. 19 杨平,霍瑞亭.硅酸盐学报,2013,41(3),409. 20 高基伟,王家邦,杨辉.硅酸盐学报,2002,30(z1),138. 21 Zeyu L U, Chen G, Hao W, et al. RSC Advances,2015,5(89),72916. 22 Asahi R, Morikawa T. Chemical Physics,2007,339(1-3),57. 23 俞成林,康勇,姚心,等.环境科学学报,2012,32(1),116. 24 钱春香,赵联芳,付大放,等.硅酸盐学报,2005,33(4),422. 25 钱春香,赵联芳,付大放,等.环境科学学报,2005,25(5),623. 26 孙尚梅,康振晋,魏志仿.化工环保,2000,20(1),11. 27 蒋伟川,王琪全,俞传明.上海环境科学,1995(5),8. 28 朱化雨,张秋艳,刘昱含,等.硅酸盐通报,2013(3),444. 29 Guo M Z, Maury-Ramirez A, Poon C S. Materials & Design,2015,88,1260. 30 李志军.纳米二氧化钛的分散性及脱酸研究.硕士学位论文,哈尔滨工业大学,2004. 31 郭璐瑶.纳米二氧化钛分散及其表面改性研究.硕士学位论文,东华大学,2015. 32 吕建,郑冀,窦富起.电工材料,2007(3),8. 33 Horst C, Kunz U, Rosenplänter A, et al. Chemical Engineering Science,1999,54(54),2849. 34 Zhu Z L, Minasny A B, Field B B D J. European Journal of Soil Science,2009,60(4),695. 35 潘蕾,吴文明,蔡雷,等.热固性树脂,2008,23(4),33. 36 Xu C L, Yang Y, Wang S Y. In: Annual Conference of Jiangsu Society of Particuology. China,2010,pp.140. 37 高濂,孙静,刘阳桥.纳米粉体的分散及表面改性,化学工业出版社,2003. 38 史建新,徐惠,张艳君,等.印染助剂,2007,24(1),5. 39 Banash M A, Croll S G. Progress in Organic Coatings,1999,35(1-4),37. 40 江贵长,官文超,郑启新.华中科技大学学报,2003,31(11),98. 41 Yamamoto M, Ohata M. Progress in Organic Coatings,1996,27(1),277. 42 Jennifer A,Lewis. Journal of the American Ceramic Society,2000,83(83),2341. 43 李国辉,李春忠.华东理工大学学报,2000,26(6),639. 44 张晓星.光催化水泥浆体的制备及对汽车尾气降解性能研究.硕士学位论文,中南大学,2014. 45 Yeon L B, Kurtis K E. Journal of the American Ceramic Society,2010,93(10),3399. 46 Baoguo M A, Hainan L I, Zhu Y, et al. Key Engineering Materials,2014,599,39. 47 马保国,梅军鹏,谭洪波,等.功能材料,2016,47(11),11162. 48 Zhang R, Cheng X, Hou P, et al. Construction & Building Materials,2015,81,35. 49 Ghosal M, Chakraborty A K. European Journal of Advances in Engineering and Technology,2015,2(8),44. 50 Jiang S, Zhou D, Zhang L, et al. Archives of Civil & Mechanical Engineering,2018,18(1),60. 51 保国,李海南,梅军鹏,等.功能材料,2015(12),12065. 52 Feng L C, Gong C W, Wu Y P, et al. Advanced Materials Research,2013,629,477. 53 Perdikatsis V. Cement & Concrete Composites,2013,36(1),33. 54 Meng T, Yu Y, Qian X, et al. Construction & Building Materials,2012,29(3),241. 55 熊国宣,邓敏,徐玲玲,等.硅酸盐学报,2006,34(9),1158. 56 熊国宣,徐玲玲,邓敏,等.功能材料与器件学报,2005,11(1),87. 57 Ruot B, Plassais A, Olive F, et al. Solar Energy,2009,83(10),1794. 58 孔德玉,杨杨,吴炎平,等.混凝土与水泥制品,2009(1),58. 59 彭兵,刘琴,柴立元,等.有色金属科学与工程,2012(6),1. 60 Folli A, Pade C, Hansen T B, et al. Cement and Concrete Research,2012,42(3),539. 61 Strini A, Schiavi L. Applied Catalysis B Environmental,2011,103(1-2),226. 62 Poon C S,Cheung E. Construction & Building Materials,2007,21(8),1746. 63 Karapati S, Giannakopoulou T, Todorova N, et al. Applied Surface Science,2014,319(1),29. 64 Janus M, Zatorska J, Czyewski A, et al. Applied Surface Science,2015,330,200. 65 熊吉如,王剑,潘庆峰,等.中国专利,CN103691414A,2014. 66 Maury-Ramirez A, Demeestere K, Belie N D. Journal of Hazardous Materials,2012,s211-212(8),218. 67 Demeestere K, Dewulf J,Witte B D, et al. Building and Environment,2008,43(4),406. 68 陈萌,储江伟,刘艳华.武汉理工大学学报,2011(11),97. 69 Li Q, Liu Q, Peng B, et al. Construction & Building Materials,2016,106,236. 70 Folli A, Macphee D E. In: Fib International PhD Symposium in Civil Engineering. Mexico,2010,pp.443. 71 Yu J C. In: Deactivation and Regeneration of Environmentally Exposed Titanium Dioxide (TiO2) Based Products. Hong Kong,2003,pp.1. 72 Mendoza C, Valle A, Castellote M, et al. Applied Catalysis B Environmental,2014,178,155.