| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
|
|
|
|
|
| Research Progress of TiO2-based Photoanode Materials for Photocatalytic Fuel Cells |
| LI Jinhan1, YU Shaobin1, SHI Mengtong1, WANG Changzheng1 WANG Qiang2
|
1 Beijing Key Laboratory of Functional Materials for Building Structure and Environment Remediation, Beijing University of Civil Engineering and Architecture, Beijing 100044, China
2 Laboratory for Micro-sized Functional Materials & College of Elementary Education, Capital Normal University, Beijing 100048, China |
|
|
|
|
Abstract Photocatalytic fuel cells employ solar energy to efficiently remove organic pollutants in water while converting chemical energy into electrical energy, which can thus achieve the dual purpose of energy recovery and pollutants removal. Currently, photocatalytic fuel cells are extensively used in water environment treatment and green energy. However, the selection and preparation of photoanode still remain key problem which restrict their large-scale applications. As one of the hot n-type semiconductor material, TiO2 has attracted considerable attention as photoanode due to its high photocatalytic activity, low cost, and good thermal stability. TiO2 nanotube arrays and TiO2 film materials, which have a large specific surface area, abundant active sites, have broad application prospects in photocatalytic fuel cells. Till now, great efforts have been made to enhance the photocatalytic performance of TiO2, such as precious metal deposition, metal and non-metal element doping. In the current review, we introduce the preparation method of TiO2 nanotube arrays and TiO2 film materials, and describe their pollutant degradation efficiency and electricity generation performance, and summarizes the influence of structure and composition on the performance of photocatalytic fuel cells. It is expected to provide a reference for the preparation of photocatalytic fuel cells with good performance.
|
|
Published: 22 April 2021
|
|
|
| Fund:National Science and Technology Major Project for Water Pollution Control and Treatment (2018ZX07110-008), Basic Scientific Research Business Expense Project of Beijing University of Civil Engineering and Architecture (X18005). |
About author:: Jinhan Lireceived her B.E. degree in water supply and drainage from Beijing University of Civil Enginee-ring and Architecture in 2019. She is currently pur-suing her master's degree at the School of Environment and Engineering, Beijing University of Civil Enginee-ring and Architecture under the supervision of prof. Changzheng Wang and prof. Qiang Wang. Her research has focused on environmental functional nanomaterials.
Changzheng Wangreceived his Ph.D. degree from Beijing Normal University in 2008. He is a professor of Beijing University of Civil Engineering and Architecture. He published more than 60 papers in domestic and foreign academic journals such as Adv. Mater., App. Catal. B, ACS Appl. Mater. Interfaces. He participated in the preparation of government documents such as National Water Saving City Assessment Stan-dards, National Water Saving City Declaration and Assessment Methods. He participated in the compilation of national standard, industry standard and local standards. He won the first prize of China Award for Science and Technology in Construction and Beijing Water Science and Technology.
Qiang Wangreceived his M.S. degree (2004) from Yunnan Normal University, Ph.D.degree (2007) from Beijing Institute of Technology, and was a visiting scholar in Benjamin J. Wiley's lab at Duke University (2011—2012). He founded the Laboratory for Micro-Sized Functional Materials in Capital Normal University. Now, he is a professor in the College of Elementary Education of Capital Normal University. His research focuses on the synthesis and applications of functional nanomaterials, and science education. |
|
|
1 Dong Z, Ren Z, Thompson S J, et al. Chemical Review, 2017, 117, 9333.
2 Guo T, Yang F N, Wang C Z, et al. Technology of Water Treatment, 2017, 43(11), 8(in Chinese).
郭涛, 杨枫楠, 汪长征, 等. 水处理技术, 2017, 43(11), 8.
3 Logan B E, Hamelers B, René R, et al. Environmental Science & Technology, 2006, 40, 5181.
4 Lovley D R. Current Opinion in Biotechnology, 2008, 19, 564.
5 Logan B E, Rabaey K. Science, 2012, 337, 686.
6 Li W W, Yu H Q, He Z. Environment Science & Technology, 2014, 7, 911.
7 Logan B E, Wallack M J, Kim K Y, et al. Environment Science & Technology Letters, 2015, 2, 206.
8 Song Y M, Xu S W, Song H, et al. Shandong Chemical Industry, 2019, 48(24), 211(in Chinese).
宋怡明, 徐少伟, 宋昊, 等. 山东化工, 2019, 48(24), 211.
9 Zhao J J. Shanxi Chemical Industry, 2020, 40(1), 24(in Chinese).
赵巾巾. 山西化工, 2020, 40(1), 24.
10 Fujishima A, Honda K. Nature, 1972, 238, 37.
11 Mo Q Y, Zeng F J, Zhang S, et al. Scientific and Technological Innovation Information, 2018(30), 79(in Chinese).
莫秋燕, 曾凡菊, 张颂, 等. 科学技术创新, 2018(30), 79.
12 Wang S M, Li D L, Sun C, et al. Applied Catalysis B: Environmental, 2014, 144, 885.
13 Ansari S A, Khan M M, Ansari M O, et al. Solar Energy Materials and Solar Cells, 2015, 141, 162.
14 Lian Z C, Wang W C, Xiao S N, et al. Scientific Reports, 2015, 5, 10461.
15 Wang Y, Yu J G, Xiao W. Journal of Materials Chemistry A, 2014, 2, 3847.
16 Sun L, Zhai J L, Li H Y, et al. ChemCatChem, 2014, 6, 339.
17 Chen J R, Qiu F X, Zhang Y, et al. Applied Surface Science, 2015, 356, 553.
18 Jiang Z F, Jiang D L, Yan Z X, et al. Applied Catalysis B: Environmental, 2015, 170-171, 195.
19 Xu J, Wu F, Jiang Q, et al. Journal of Molecular Catalysis A: Chemical, 2015, 403, 77.
20 Liang C, Wu Y Q, Wang D W, et al. Materials Reports, 2019, 33(S2), 267(in Chinese).
梁辰, 吴艳青, 王大伟, 等. 材料导报, 2019, 33(S2), 267.
21 Su D, Dou S, Wang G. Chemistry of Materials, 2015, 27, 6022.
22 Huang L, Wang J, Zhu Y, et al. Journal of Alloys and Compounds, 2019, 8, 925.
23 Li X T, Wang J, Guo Y, et al. China Ceramic Industry, 2020, 27(1), 30(in Chinese).
李孝通, 王竞, 郭玉, 等. 中国陶瓷工业, 2020, 27(1), 30.
24 Chen W, Zhou P, Guo L, et al. Materials Research and Application, 2020, 14(1), 68(in Chinese).
陈文, 周鹏, 郭鲤, 等. 材料研究与应用, 2020, 14(1), 68.
25 Wu N, Dong Y H, Ji X Y, et al. CIESC Journal, 2020, 71(2), 831(in Chinese).
吴娜, 董依慧, 吉晓燕, 等. 化工学报, 2020, 71(2), 831.
26 Xia B, Yao J J, Han C X, et al. Chemicke Zvesti, 2018, 72, 359.
27 Chen X Y, Yao J J, Xia B, et al. Journal of Hazardous Materials,2020, 383, 121220.
28 Li N, Tang S F, Rao Y D, et al. Electrochimica Acta, 2018, 270, 330.
29 Liu X H, Xing Z H, Chen Q Y, et al. Chemosphere, 2019, 237, 124457.
30 Ye Y, Bruning H, Li X L, et al. Chemical Engineering Journal, 2018, 354, 553.
31 Wang J Q, Liu D, Zhou J, et al. Journal of East China Normal University (Natural Science), 2020(1), 93(in Chinese).
王剑桥, 刘冬, 周君, 等. 华东师范大学学报(自然科学版), 2020(1), 93.
32 Li J Y. Study on TiO2/Ti-Cu2O/Cu based photocatalytic fuel cell. Master's Thesis, Shanghai Jiao Tong University, China, 2014(in Chinese).
李建勇. TiO2/Ti-Cu2O/Cu光催化废水燃料电池的设计与性能研究. 硕士学位论文, 上海交通大学, 2014.
33 Liu Y B. Photo (electro) catalytic degradation of organic pollutants by novel electrode materials and comprehensive utilization of the chemical energy of pollutants. Ph.D. Thesis, Shanghai Jiao Tong University, China, 2011(in Chinese).
刘艳彪. 新型电极材料光/电催化降解有机污染物及污染物化学能的综合利用.博士学位论文, 上海交通大学, 2011.
34 Li D Y, Zhang W T, Zhang C. Materials Reports B: Research Papers, 2019, 33(12), 3900(in Chinese).
李大玉, 张文韬, 张超. 材料导报:研究篇, 2019, 33(12), 3900.
35 Yang J W. Master's Thesis, Huazhong University of Science and Techno-logy, China, 2016(in Chinese).
杨婧薇. 基于TiO2纳米管的可见光型光催化废水燃料电池. 硕士学位论文, 华中科技大学, 2016.
36 Xiong J L, Li T, Liu H, et al. Science Technology and Engineering,2017, 17(18), 126(in Chinese).
熊金磊, 李亭, 刘浩, 等. 科学技术与工程, 2017, 17(18), 126.
37 Chu Y C. Preparation of photocatalytic fuel cell based on BiVO4/TiO2 NT and Cu2O/TiO2 NT and its performance. Masters Thesis, Northeast Normal University. China, 2019(in Chinese).
初义聪. 基于BiVO4/TiO2 NT和Cu2O/TiO2 NT的双极光催化燃料电池设计制备及性能研究. 东北师范大学, 2019.
38 Bai J, Wang R, Li Y P, et al. Journal of Hazardous Materials, 2016, 311, 51.
39 Wang R. Preparation of heterojunction photoelectrode and its application in photocatalytic wastewater fuel cell. Masters Thesis, Shanghai Jiao Tong University, China, 2017(in Chinese).
王芮. 异质结光电极的制备及其在光催化废水燃料电池中的应用. 上海交通大学, 2017.
40 Wu M Y. The application of metal modified TiO2 nanotube arrays on photoelectrocatalytic reduction of Cr(Ⅵ). Master's Thesis, Harbin Engineering University, China, 2015(in Chinese).
吴梦瑶. 金属改性TiO2纳米管阵列光电催化还原Cr(Ⅵ)的研究.哈尔滨工程大学, 2015.
41 Yang F N. The application of TiO2 composite nano-array to photocatalytic fuel cell. Master's Thesis, Beijing University of Civil Engineering and Architecture, China, 2019(in Chinese).
杨枫楠. TiO2复合纳米阵列用于光催化燃料电池的研究. 北京建筑大学, 2019.
42 Ghicov A, Macak J M, Tsuchiya H, et al. Chemical Physics Letters, 2006, 419, 426.
43 Quan X, Yang S G, Ruan, X L, et al. Environmental Science and Technology, 2005, 39, 3770.
44 Xu Y. Research on electricity production and the efficiency of the degradation of carbamazepine based on N, F doped TiO2 NTs anode photocatalytic fuel cell. Master's Thesis, Chongqing University, China, 2016(in Chinese).
徐洋. 基于N, F掺杂TiO2 NTs阳极的光催化燃料电池产电及降解卡马西平的效能研究. 重庆大学, 2016.
45 Han C X. Research on the efficiency and mechanism of the degradation of ofloxacin based on UVA-LED/TiO2 anode photocatalytic fuel cell. Ma-ster's Thesis, Chongqing University, China, 2017(in Chinese).
韩晨曦. UVA-LED/TiO2纳米管阵列光催化燃料电池降解氧氟沙星效能研究. 重庆大学, 2017.
46 Xia Z L, Liu S M, Guo Y, et al. China Ceramic Industry, 2020, 27(1), 41(in Chinese).
夏泽林, 刘世民, 郭玉, 等. 中国陶瓷工业, 2020, 27(1), 41.
47 Lv Q. Preparation of visible light catalytic material and its application in degrading dye wastewater from fuel cells. Master's Thesis, Inner Mongolia University, China, 2019(in Chinese).
吕庆. 可见光催化材料制备及其在燃料电池降解染料废水中的应用. 硕士学位论文,内蒙古大学, 2019.
48 Daniyan A A, Umoru L E, Olunlade B. Journal of Minerals and Mate-rials Characterization and Engineering, 2013, 1, 138.
49 Yang D W, Yang P Z. Journal of Yunnan Normal University (Natural Sciences Edition), 2020, 40(2), 15(in Chinese).
杨德威,杨培志.云南师范大学学报(自然科学版),2020,40(2),15.
50 Kania A, Nolbrzak P, Radoń A, et al. Materials (Basel, Switzerland), 2020, 13, 1065.
51 Yang K, He C, Xu W, et al. Industrial Water Treatment, 2019, 39(3), 80(in Chinese).
杨开, 何琛, 徐伟, 等. 工业水处理, 2019, 39(3), 80.
52 Li K, Zhang H B, Tang T T, et al. Water Research, 2014, 62, 1.
53 Lin S Z, Wang S H. Journal of Northeast Electric Power University, 2016, 36(3), 69(in Chinese).
林松竹, 王守航. 东北电力大学学报, 2016, 36(3), 69.
54 Fu S Z, Deng B Q, Ma D M, et al. ChemEngineering, 2018, 2, 20.
55 Kee M W, Lam S M, Sin J C, et al. Journal of Photochemistry and Photobiology A: Chemistry, 2020, 391, 112353.
56 Lam S M, Sin J C, Lin H, et al. Chemosphere, 2020, 245, 125565.
57 Yang C, He Y, Li K, et al. Catalysts, 2016, 6, 114.
58 Yang K, Xu Y L, Zhong D J. Environmental Chemistry, 2018, 37(1), 108(in Chinese).
杨开, 徐云兰, 钟登杰. 环境化学, 2018, 37(1), 108.
59 Liu J, Xia M, Chen R, et al. Separation & Purification Technology, 2019, 229, 115821.
60 Kané R, Liu L F, Noor A N, et al. Electrochimica Acta, 2019, 298, 430. |
| [1] |
WU Yanxia, LIANG Hailong, CHEN Xin, CHEN Chen, WANG Xianzhong, DAI Changyou, HU Liming, CHEN Yufeng. Effect of Element (Ce, Co, La, Sn) Doping on Denitration Activity of V-Mo/TiO2 Catalysts[J]. Materials Reports, 2021, 35(6): 6020-6027. |
|
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2021, Vol. 35 
