Abstract: The consumption of non-renewable energy resources such as coal, oil and natural gas leads to more and more se-rious environment pollution problems, which makes the utilization of clean and renewable energy deserve immediate and intense attention. Photocatalytic hydrogen evolution has been considered to be one of the effective approaches to solve fossil energy shortage and environmental pollution problems. However, the photocatalytic hydrogen evolution reaction system is complicated, in which the co-catalyst have a crucial effect to the photocatalyst’s efficiency and can effectively promote the hydrogen evolution rate during the photocatalytic process, hence the development of cheap and efficient co-catalyst has become one of the research focus. This paper briefly introduces the reaction mechanism of photocatalytic hydrogen evolution and the roles of co-catalysts in the photocatalytic systems, summarizes the variety of co-catalysts and relevant research, and analyzes the characteristics and mechanism of several principal types co-catalysts including metals, transition metal sulfides, transition metal oxides, transition metal hydroxides, phosphides, and composites. The paper ends with a prospective presentation of the future research directions, and is expected to provide reference for the innovation and development of highly efficient photocatalysts applying to hydrogen evolution systems.
李旭力, 王晓静, 赵君, 李玉佩, 李发堂, 陈学敏. 催化分解水制氢体系助催化剂研究进展[J]. 《材料导报》期刊社, 2018, 32(7): 1057-1064.
LI Xuli, WANG Xiaojing, ZHAO Jun, LI Yupei, LI Fatang, CHEN Xuemin. Progress of Co-catalysts in the Systems of Photocatalytic Hydrogen Evolution. Materials Reports, 2018, 32(7): 1057-1064.
1 Fujishima A,Honda K. Electrochemical photocatalysis of water at semiconductor electrode[J].Nature,1972,238(5358):37. 2 Xu J H, Tan L H, Kou B, et al. Modification of graphtic carbon nitride photocatalyst[J].Progress in Chemistry,2016,28(1):131(in Chinese). 徐建华,谈玲华,寇波,等.类石墨相C3N4光催化剂改性研究[J].化学进展,2016,28(1):131. 3 Lu Q,Yu Y,Ma Q,et al. 2D Transition-metal-dichalcogenide-nanosheet-based composites for photocatalytic and electrocatalytic hydrogen evolution reactions[J].Advanced Materials,2016,28(10):1917. 4 Chu T T, Wang H, Feng C X, et al. Progress of photocatalysts for water splitting by solar energy[J].Chemical Industry & Engineering Progress,2012,31(10):2228(in Chinese). 楚婷婷,王慧,冯彩霞,等.可见光分解水制氢催化剂研究进展[J].化工进展,2012,31(10):2228. 5 Zhang L F, Hu Z P, Liu X Y, et al. Noble-metal-free co-catalysts for TiO2-based photocatalytic H2-evolution half reaction in water splitting[J].Progress in Chemistry,2016,28(10):1474(in Chinese). 张凌峰,胡忠攀,刘歆颖,等.TiO2基光解水析氢非贵金属共催化剂的研究[J].化学进展,2016,28(10):1474. 6 Xie Y P, Wang G S, Zhang E L, et al. Photocatalytic hydrogen evolution from water splitting using semiconductors: Advance, challenge and prospects[J].Chinese Journal of Inorganic Chemistry,2017,33(2):177(in Chinese). 谢英鹏,王国胜,张恩磊,等.半导体光解水制氢研究:现状、挑战及展望[J].无机化学学报,2017,33(2):177. 7 Wang X J, Zhao Y, Li F T, et al. A chelation strategy for in-situ constructing surface oxygen vacancy on {001} facets exposed BiOBr nanosheets[J].Scientific Reportsactions,2016,6:24918. 8 Iwashina K, Iwaseab A, Kudo A. Visible-light-responsive CuLi1/3-Ti2/3O2powders prepared by a molten CuCl treatment of Li2TiO3 for photocatalytic H2 evolution and Z-schematic water splitting[J].Chemistry of Materials,2015,6:687. 9 Wang X J, TianX, Li F T, et al. The synergy between Ti species and g-C3N4 by doping and hybridization for the enhancement of photocatalytic H2 evolution[J].Dalton Transactions,2015,44(40):17859. 10Osterloh F E. Inorganic nanostructures for photoelectrochemical and photocatalytic water splitting[J].Chemical Society Reviews,2013,42:2294. 11Jiang T F, Xie T F, Chen L, et al. Carrier concentration-dependent electron transfer in Cu2O/ZnO nanorod arrays and their photocatalytic performance[J].Nanoscale,2013,5:2938. 12Wang X J, Tian X, Li F T, et al. Synchronous surface hydroxylation and porous modification of g-C3N4 for enhanced photocatalytic H2 evolution efficiency[J].International Journal of Hydrogen Energy,2016,41(6):3888. 13 Wang X J, Liu C, Li X L, et al. Construction of g-C3N4 /Al2O3, hybrids via in-situ acidification and exfoliation with enhanced photoca-talytic activity[J].Applied Surface Science,2017,394:340. 14 Zhu Y P, Ren T Z, Yuan Z Y. Mesoporous phosphorus-doped g-C3N4 nanostructured flowers with superior photocatalytic hydrogen evolution performance[J].ACS Applied Materials & Interfaces,2015,7(30):16850. 15 Zhang G, Li G, Wang X. Surface modification of carbon nitride polymers by core-shell nickel/nickel oxide cocatalysts for hydrogen evolution photocatalysis[J].Chemcatchem,2015,7:2864. 16 Ma L, Shen X, Zhou H, et al. CoP nanoparticles deposited on reduced graphene oxide sheets as an active electrocatalyst for the hydrogen evolution reaction[J].Journal of Materials Chemistry A,2015,3:5337. 17 Linsebigler A L, Lu G, Yates J T. Photocatalysis on TiO2 surfaces: Principles, mechanisms, and selected results[J].Chemical Reviews,1995,95:735. 18 Chen X, Shen S, Guo L, et al. Semiconductor-based photocatalytic hydrogen generation[J].Chemical Reviews,2010,110:6503. 19 Ai Z Y, Zhao W R, Dai J S, et al. Modification of photocatalysts for H2 evolution from water photocatalyzation[J].Journal of Chemical Engineering of Chinese Universities,2016,30(3):508(in Chinese). 艾珠玉,赵伟荣,戴九松,等.光催化分解水制氢催化剂的修饰与改性[J].高校化学工程学报,2016,30(3):508. 20Liu W F, Zhou R L, Wang Y Z. Research progress on modification of TiO2 photocatalyst[J].Chemical Industry and Engineering Progress,2016,35(8):2446(in Chinese). 刘文芳,周汝利,王燕子.光催化剂TiO2改性的研究进展[J].化工进展,2016,35(8):2446. 21Yang Y Z, Chang C H, Idriss H. Photocatalytic production of hydrogen form ethanol over M/TiO2 catalysts (M=Pd, Pt or Rh)[J].Applied Catalysis B-Environmental,2006,67:217. 22Bao N, Shen L, Takata T, et al. Highly ordered Pt-loaded CdS nanowire arrays for photocatalytic hydrogen production under visible light[J].Chemistry Letters,2006,35(3):318. 23 Wang F C, Liu C H, Liu C W, et al. Effect of Pt loading order on photocatalytic activity of Pt/TiO2 nanofiber in generation of H2 from neat ethanol[J].Journal of Physical Chemistry C,2009,113(31):13832. 24 Kiyoung L, Robert H, Marco A, et al. Intrinsic Au decoration of growing TiO2 nanotubes and formation of a high-efficiency photoca-talyst for H2production[J].Advanced Materials,2013,25(42):6133. 25 Sasaki T, Koshizaki N, Koinuma M, et al. Preparation of M/TiO2 (M=Au, Pt) nanocomposite films using co-sputtering method[J].Nanostructured Materials,1997,8(12):511. 26 Yang T T, Chen W T, Hsu Y J, et al. Interfacial charge carrier dynamics in coreshell Au-CdS nanocrystals[J].Journal of Physical Chemistry C,2010,114(26):11414. 27 Boccuzzi F, Chiorino A, Manzoli M, et al. Gold, silver and copper catalysts supported on TiO2 for pure hydrogen production[J].Catalysis Today,2002,75:169. 28 Sreethawong T, Yoshikawa S. Comparative investigation on photocatalytic hydrogen evolution over Cu-, Pd-, and Au-loaded mesoporous TiO2 photocatalysts[J].Catalysis Communications,2005,6:661. 29 Zhang X J, Chu G H, Li S B, et al. Photocatalytic hydrogen evolution over M/TiO2 (M=Pt,Pd,Au,Rh)with glucose as electron donor[J].Journal of Molecular Catalysis,2017,21(3):239. 30Subramanian V, Wolf E E, Kamat P V. Catalysis with TiO2/gold nanocomposites. Effect of metal particle size on the fermi level equi-libration[J].Journal of the American Chemical Society,2004,126(15):4943. 31Bamwenda G R, Tsubota S, Nakamura T, et al. Photoassisted hydrogen production from a water-ethanol solution: A comparison of activities of Au-TiO2 and Pt-TiO2[J].Journal of Photochemistry & Photobiology A:Chemistry,1995,89(2):177. 32Murdoch M, Waterhouse G I N, Nadeem M A, et al. The effect of gold loading and particle size on photocatalytic hydrogen production from ethanol over Au/TiO2 nanoparticles[J].Nature Chemistry,2011,3(6):489. 33 Chiarello G L, Selli E, Forni L. Photocatalytic hydrogen production over flame spray pyrolysis-synthesised TiO2 and Au/TiO2[J].Applied Catalysis B:Environmental,2008,84:332. 34 Jovic V, Al-Azri Z H N, Chen W T, et al. Photocatalytic H2 production from ethanol-water mixtures over Pt/TiO2 and Au/TiO2 photocatalysts: A comparative study[J].Topics in Catalysis,2013,56(12):1139. 35 Onsuratoom S, Chavadej S, Sreethawong T. Hydrogen production from water splitting under UV light irradiation over Ag-loaded mesoporous-assembled TiO2-ZrO2 mixed oxide nanocrystal photocatalysts[J].International Journal of Hydrogen Energy,2011,36(36):5246. 36 Zhou N, Polavarapu L, Gao N Y, et al. TiO2 coated Au/Ag nanorods with enhanced photocatalytic activity under visible light irradiation[J].Nanoscale,2013,5:4236. 37 Verbruggen S. W, Keulemans M, Filippousi M, et al. Plasmonic gold-silver alloy on TiO2 photocatalysts with tunable visible light activity[J].Applied Catalysis B:Environmental,2014,156-157:116. 38 Zhang Y, Park S J. Au-Pd bimetallic alloy nanoparticle-decorated BiPO4 nanorods for enhanced photocatalytic oxidation of trichloroethylene[J].Journal of Catalysis,2017,355:1. 39 Su R, Tiruvalam R, Logsdail A J, et al. Designer titania-supported Au-Pd nanoparticles for efficient photocatalytic hydrogen production[J].ACS Nano,2014,8(4):3490. 40Zhang Y H, Zhang N, Tang Z R, et al. Graphene oxide as a surfactant and support for in-situ synthesis of Au-Pd nanoalloys with improved visible light photocatalytic activity[J].Bmc Genomics,2014,15(1):1. 41Kang Q, Wang T, Li P, et al. Photocatalytic reduction of carbon dioxide by hydrous hydrazine over Au-Cu alloy nanoparticles supported on SrTiO3/TiO2 coaxial nanotube arrays[J].Angewandte Chemie-International Edition,2015,54(3):841. 42Neatu S, Maciáagulló J A, Concepción P, et al. Gold-copper nanoalloys supported on TiO2 as photocatalysts for CO2 reduction by water[J].Journal of the American Chemical Society,2014,136(45):15969. 43 Montesnavajas P, Serra M, Garcia H. Influence of the irradiation wavelength on the photocatalytic activity of Au-Pt nanoalloys supported on TiO2 for hydrogen generation from water[J].Catalysis Science & Technology,2013,3(9):2252. 44 Hung S F, Yu Y C, Suen N T, et al. The synergistic effect of a well-defined Au@Pt core-shell nanostructure toward photocatalytic hydrogen generation: Interface engineering to improve the Schottky barrier and hydrogen-evolved kinetics[J].Chemical Communications,2016,52(8):1567. 45 Shiraishi Y, Takeda Y, Sugano Y, et al. Highly efficient photocatalytic dehalogenation of organic halides on TiO2 loaded with bimetallic Pd-Pt alloy nanoparticles[J].Cheminform,2011,47:7863. 46 Rosseler O, Ulhaq-Bouillet C, Bonnefont A, et al. Structural and electronic effects in bimetallic PdPt nanoparticles on TiO2 for improved photocatalytic oxidation of CO in the presence of humidity[J].Applied Catalysis B:Environmental,2015,166-167:381. 47 Luna A L, Novoseltceva E, Louarn E, et al. Synergetic effect of Ni and Au nanoparticles synthesized on titania particles for efficient photocatalytic hydrogen production[J].Applied Catalysis B:Environmental,2016,191:18. 48 Ding J, Li X, Chen L, et al. Au-Pt alloy nanoparticles site-selectively deposited on CaIn2S4 nanosteps as efficient photocatalysts for hydrogen production[J].Journal of Materials Chemistry A,2016,4:12630. 49 Zhang Z, Cao S W, Liao Y, et al. Selective photocatalytic decomposition of formic acid over AuPd nanoparticle-decorated TiO2 nanofibers toward high-yield hydrogen production[J].Applied Catalysis B:Environmental,2015,162:204. 50Chen W T, Chan A, Sun D, et al. Ni/TiO2: A promising low-cost photocatalytic system for solar H2 production from ethanol-water mixtures[J].Journal of Catalysis,2015,326:43. 51Chen S, Chen X, Jiang Q, et al. Promotion effect of nickel loaded on CdS for photocatalytic H2 production in lactic acid solution[J].Applied Surface Science,2014,316(1):590. 52Indra A, Menezes P W, Kailasam K, et al. Nickel as a co-catalyst for photocatalytic hydrogen evolution on graphitic-carbon nitride (sg-CN): What is the nature of the active species[J].Chemical Communications,2016,52:104. 53 Kong L, Dong Y, Jiang P, et al. Light-assisted rapid preparation of Ni/g-C3N4 magnetic composite for robust photocatalytic H2 evolution from water[J].Journal of Materials Chemistry A,2016,4:9998. 54 Zhang K,Guo L. Metal sulphide semiconductors for photocatalytic hydrogen production[J].Catalysis Science & Technology,2013,3(7):1672. 55 Hong S, Kumar D P, Reddy D A, et al. Excellent photocatalytic hydrogen production over CdS nanorods via using noble metal-free copper molybdenum sulfide (Cu2MoS4) nanosheets as co-catalysts[J].Applied Surface Science,2017,396:421. 56 Han B, Liu S, Zhang N, et al. One-dimensional CdS@MoS2 core-shell nanowires for boosted photocatalytic hydrogen evolution under visible light[J].Applied Catalysis B:Environmental,2016,202:298. 57 Zong X, Yan H J, Wu G P, et al. Enhancement of photocatalytic H2 evolution on CdS by loading MoS2 as cocatalyst under visible light irradiation[J].Journal of the American Chemical Society,2008,130(23):7176. 58 Yin X L, Li L L, Jiang W J, et al. MoS2/CdS nanosheets-on-nanorod heterostructure for highly efficient photocatalytic H2 generation under visible light irradiation[J].Acs Applied Materials & Interfaces,2016,8(24):15258. 59 Zong Xu, Han J F, Ma G J, et al. Photocatalytic H2 evolution on CdS loaded with WS2 as cocatalyst under visible light irradiation[J].Journal of Physical Chemistry C,2011,115(24):12202. 60Zhang L J, Xie T F, Wang D J, et al. Noble-metal-free CuS/CdS composites for photocatalytic H2 evolution and its photogenerated charge transfer properties[J].International Journal of Hydrogen Energy,2013,38(27):11811. 61Zhang J, Yu J, Zhang Y, et al. Visible light photocatalytic H2-production activity of CuS/ZnS porous nanosheets based on photoinduced interfacial charge transfer[J].Nano Letters,2011,11:4774. 62García-Mendoza C, Oros-Ruiz S, Hernández-Gordillo A, et al. Sui-table preparation of Bi2S3 nanorods-TiO2 heterojunction semiconductors with improved photocatalytic hydrogen production from water/methanol decomposition[J].Journal of Chemical Technology & Biotechnology,2016,91(8):2198. 63 Hong J, Wang Y, Wang Y, et al. Noble-metal-free NiS/C3N4 for efficient photocatalytic hydrogen evolution from water[J].ChemSusChem,2013,6(12):2263. 64 Zhang W, Wang Y, Wang Z, et al. Highly efficient and noble metal-free NiS/CdS photocatalysts for H2 evolution from lactic acid sacrificial solution under visible light[J].Chemical Communications,2010,46(40):7631. 65 Wang Q, Yun G, Bai Y, et al. CuS, NiS as co-catalyst for enhanced photocatalytic hydrogen evolution over TiO2[J].International Journal of Hydrogen Energy,2014,39(25):13421. 66 Li L, Xu L, Shi W, et al. Facile preparation and size-dependent photocatalytic activity of Cu2O nanocrystals modified titania for hydrogen evolution[J].International Journal of Hydrogen Energy,2013,38(2):816. 67 Hu C C, Teng H. Structural features of p-type semiconducting NiO as a co-catalyst for photocatalytic water splitting[J].Journal of Catalysis,2010,272(1):1. 68 Yu J, Hai Y, Cheng B. Enhanced photocatalytic H2-production activity of TiO2 by Ni(OH)2 cluster modification[J].Journal of Physical Chemistry C,2011,115(11):4953. 69 Yu J, Wang S, Cheng B, et al. Noble metal-free Ni(OH)2/g-C3N4 composite photocatalyst with enhanced visible-light photocatalytic H2-production activity[J].Catalysis Science & Technology,2013,3(7):1782. 70Ran J, Yu J, Jaroniec M. Ni(OH)2 modified CdS nanorods for highly efficient visible-light-driven photocatalytic H2 gene-ration[J].Green Chemistry,2011,13(10):2708. 71Yu J, Ran J. Facile preparation and enhanced photocatalytic H2-production activity of Cu(OH)2 cluster modified TiO2[J].Energy & Environmental Science,2011,4(4):1364. 72Dang H, Dong X, Dong Y, et al. TiO2 nanotubes coupled with nano-Cu(OH)2 for highly efficient photocatalytic hydrogen production[J].International Journal of Hydrogen Energy,2013,38(5):2126. 73 Zhou X, Luo Z, Tao P, et al. Facile preparation and enhanced photocatalytic H2-production activity of Cu(OH)2 nanospheres modified porous g-C3N4[J].Materials Chemistry & Physics,2014,143(3):1462. 74 Zhang L J, Zheng R, Li S, et al. Enhanced photocatalytic H2 gene-ration on cadmium sulfide nanorods with cobalt hydroxide as cocatalyst and insights into their photogenerated charge transfer properties[J].ACS Applied Materials & Interfaces,2014,6(16):12998. 75 Liu P, Rodriguez J A. Catalysts for hydrogen evolution from the[NiFe] hydrogenase to the Ni2P(001) surface: The importance of ensemble effect[J].Journal of the American Chemical Society,2005,127:14871. 76 Dong Y, Kong L, Wang G, et al. Photochemical synthesis of CoxP as cocatalyst for boosting photocatalytic H2, production via spatial charge separation[J].Applied Catalysis B:Environmental,2017,211:245. 77 Popczun E J, McKone J R, Read C G, et al. Nanostructured nickel phosphide as an electrocatalyst for the hydrogen evolution reaction[J].Journal of the American Chemical Society,2013,135:9267. 78 Popczun E J, Read C G, Roske C W, et al. Highly active electrocatalysis of the hydrogen evolution reaction by cobalt phosphide nano-particles[J].Angewandte Chemie-International Edition,2014,53:5427. 79 Xing Z, Liu Q, Asiri A M, et al. Closely interconnected network of molybdenum phosphide nanoparticles: A highly efficient electrocatalyst for generating hydrogen from water[J].Advanced Materials,2014,26:5702. 80Sun Z, Zheng H, Li J, et al. Extraordinarily efficient photocatalytic hydrogen evolution in water using semiconductor nanorods integra-ted with crystalline Ni2P cocatalysts[J].Energy & Environmental Science,2015,8(9):2668. 81Chen Y, Qin Z. General applicability of nanocrystalline Ni2P as a noble-metal-free cocatalyst to boost photocatalytic hydrogen generation[J].Catalysis Science & Technology,2016,6:8212. 82Indra A, Acharjya A, Menezes P W, et al. Boosting visible-light-driven photocatalytic hydrogen evolution with an integrated nickel phosphide-carbon nitride system[J].Angewandte Chemie-International Edition,2017,56:1653. 83 Cao S, Chen Y, Wang C J, et al. Spectacular photocatalytic hydrogen evolution using metal-phosphide/CdS hybrid catalysts under sunlight irradiation[J].Chemical Communications,2015,51(41):8708. 84 Amirav L, Alivisatos A P. Photocatalytic hydrogen production with tunable nanorod heterostructures[J].Journal of Physical Chemistry Letters,2010,1(7):1051. 85 Lingampalli S R, Gautam U K, Rao C N R. Highly efficient photocatalytic hydrogen generation by solution-processed ZnO/Pt/CdS, ZnO/Pt/Cd1-xZnxS and ZnO/Pt/CdS1-xSex hybrid nanostructures[J].Energy & Environmental Science,2013,6:3589. 86 Chen Y, Wang L, Lu G, et al. Nanoparticles enwrapped with nanotubes: A unique architecture of CdS/titanate nanotubes for efficient photocatalytic hydrogen production from water[J].Journal of Materials Chemistry,2011,21:5134. 87 Cheng H, Lv X J, Cao S, et al. Robustly photogenerating H2 in water using FeP/CdS catalyst under solar irradiation[J].Scientific Reports,2016,6:19846. 88 Xiao P, Sk M A, Thia L, et al. Molybdenum phosphide as an efficient electrocatalyst for the hydrogen evolution reaction[J].Energy & Environmental Science,2014,7:2624. 89 Yue Q, Wan Y, Sun Z, et al. MoP is a novel, noble-metal-free cocatalyst for enhanced photocatalytic hydrogen production in water under visible light[J].Journal of Materials Chemistry A,2015,3(33):16941. 90Yue X, Yi S, Wang R, et al. Cadmium sulfide and nickel synergetic co-catalysts supported on graphitic carbon nitride for visible-light-driven photocatalytic hydrogen evolution[J].Scientific Reports,2016,6:22268. 91Lin P B, Yang Y, Chen W, et al. Hydrothermal synthesis and acti-vity of NiS-PdS/CdS catalysts forphotocatalytic hydrogen evolution under visible light irradiation[J].Acta Physico-Chimica Sinica,2013,29(6):1313(in Chinese). 林培宾,杨俞,陈威,等.NiS-PdS/CdS光催化剂的水热法合成及其可见光分解水产氢性能[J].物理化学学报,2013,29(6):1313. 92Yan H, Yang J, Ma G, et al. Visible-light-driven hydrogen production with extremely high quantum efficiency on Pt-PdS/CdS photocatalyst[J].Journal of Catalysis,2009,266(2):165. 93 Yang J, Yan H, Wang X, et al. Roles of cocatalysts in Pt-PdS/CdS with exceptionally high quantum efficiency for photocatalytic hydrogen production[J].Journal of Catalysis,2012,290(6):151. 94 Wang D, Hisatomi T, Takata T, et al. Core/shell photocatalyst with spatially separated co-catalysts for efficient reduction and oxidation of water[J].Angewandte Chemie-International Edition,2013,52(43):11252.
渝公网安备50019002502923号 版权所有:《材料导报》编辑部
2018, Vol. 32 
