摘要
Developing earth-abundant-electrocatalysts for hydrogen evolution reaction is one of the promising ways to achieve efficient water-splitting for hydrogen production(a clean chemical fuel). This paper reviews the activity, stability and durability for hydrogen evolution reaction in alkaline medium of different types of recently reported potential electrocatalysts such as Ni, Co, NiCo, Fe, Cu, W, Mo, Se, Mn, Zn,V, and metal free based earth-abundant-electrocatalysts. Further, this paper reviews the strategies used to achieve the remarkably low overpotential(including η10: ≤ 35 m V), high long term stability(including ≥ 100 h) and high durability(including ≥ 5000 cycles) of potential earth-abundant-electrocatalysts for hydrogen evolution reaction in alkaline medium and those are better or well comparable with the state-of-the-art, noble, Pt/C electrocatalyst. Finally, this paper summarizes the efficient strategies such as preparing porous structured materials, preparing nanostructured materials with superaerophobic surface, preparing nanostructured materials, preparing carbon composites/integrating electrocatalysts with carbon, preparing amorphous materials, preparing materials with oxygen vacancies/defects, preparing metal chalcogenides, preparing bimetallic/multi-metallic materials, doping metals or heteroatoms, preparing electrocatalysts with core-shell structure, decorating electrocatalysts with amines, preparing homojunction/heterojunction structured materials, preparing hollow structured materials, and preparing boronrich surface to enhance the activity, stability, and durability for HER.
Developing earth-abundant-electrocatalysts for hydrogen evolution reaction is one of the promising ways to achieve efficient water-splitting for hydrogen production(a clean chemical fuel). This paper reviews the activity, stability and durability for hydrogen evolution reaction in alkaline medium of different types of recently reported potential electrocatalysts such as Ni, Co, NiCo, Fe, Cu, W, Mo, Se, Mn, Zn,V, and metal free based earth-abundant-electrocatalysts. Further, this paper reviews the strategies used to achieve the remarkably low overpotential(including η10: ≤ 35 m V), high long term stability(including ≥ 100 h) and high durability(including ≥ 5000 cycles) of potential earth-abundant-electrocatalysts for hydrogen evolution reaction in alkaline medium and those are better or well comparable with the state-of-the-art, noble, Pt/C electrocatalyst. Finally, this paper summarizes the efficient strategies such as preparing porous structured materials, preparing nanostructured materials with superaerophobic surface, preparing nanostructured materials, preparing carbon composites/integrating electrocatalysts with carbon, preparing amorphous materials, preparing materials with oxygen vacancies/defects, preparing metal chalcogenides, preparing bimetallic/multi-metallic materials, doping metals or heteroatoms, preparing electrocatalysts with core-shell structure, decorating electrocatalysts with amines, preparing homojunction/heterojunction structured materials, preparing hollow structured materials, and preparing boronrich surface to enhance the activity, stability, and durability for HER.
引文
[1]M.I.Jamesh,X.Sun,J.Power Sources 400(2018)31-68.
[2]M.I.Jamesh,J.Energy Chem.(2018),doi:10.1016/j.jechem.2018.1006.1011.
[3]M.I.Jamesh,J.Power Sources 333(2016)213-236.
[4]S.B.Lai,M.I.Jamesh,X.C.Wu,Y.L.Dong,J.H.Wang,M.Gao,J.F.Liu,X.M.Sun,Rare Met.36(5)(2017)381-396.
[5]M.I.Jamesh,A.S.Prakash,J.Power Sources 378(2018)268-300.
[6]H.Wang,H.Dai,Chem.Soc.Rev 42(7)(2013)3088-3113.
[7]J.A.Turner,Science 305(5686)(2004)972-974.
[8]S.Chu,A.Majumdar,Nature 488(7411)(2012)294-303.
[9]Y.Liang,Y.Li,H.Wang,J.Zhou,J.Wang,T.Regier,H.Dai,Nat.Mater 10(10)(2011)780-786.
[10]M.D.Symes,L.Cronin,Nat.Chem 5(5)(2013)403-409.
[11]T.R.Cook,D.K.Dogutan,S.Y.Reece,Y.Surendranath,T.S.Teets,D.G.Nocera,Chem.Rev 110(11)(2010)6474-6502.
[12]M.Sathiya,K.Hemalatha,K.Ramesha,J.M.Tarascon,A.S.Prakash,Chem.Mater 24(10)(2012)1846-1853.
[13]M.G.Walter,E.L.Warren,J.R.McKone,S.W.Boettcher,Q.Mi,E.A.Santori,N.S.Lewis,Chem.Rev 110(11)(2010)6446-6473.
[14]K.Zeng,D.Zhang,Prog.Energy Combust.Sci 36(3)(2010)307-326.
[15]C.C.L.Mc Crory,S.Jung,I.M.Ferrer,S.M.Chatman,J.C.Peters,T.F.Jaramillo,J.Am.Chem.Soc.137(13)(2015)4347-4357.
[16]Y.Li,H.Zhang,T.Xu,Z.Lu,X.Wu,P.Wan,X.Sun,L.Jiang,Adv.Funct.Mater25(11)(2015)1737-1744.
[17]L.C.Seitz,C.F.Dickens,K.Nishio,Y.Hikita,J.Montoya,A.Doyle,C.Kirk,A.Vojvodic,H.Y.Hwang,J.K.Norskov,T.F.Jaramillo,Science 353(6303)(2016)1011-1014.
[18]B.Zhang,X.Zheng,O.Voznyy,R.Comin,M.Bajdich,M.García-Melchor,L.Han,J.Xu,M.Liu,L.Zheng,F.P.García de Arquer,C.T.Dinh,F.Fan,M.Yuan,E.Yassitepe,N.Chen,T.Regier,P.Liu,Y.Li,P.De Luna,A.Janmohamed,H.L.Xin,H.Yang,A.Vojvodic,E.H.Sargent,Science 352(6283)(2016)333-337.
[19]J.Luo,J.-H.Im,M.T.Mayer,M.Schreier,M.K.Nazeeruddin,N.-G.Park,S.D.Tilley,H.J.Fan,M.Gr?tzel,Science 345(6204)(2014)1593-1596.
[20]Y.Hao,Y.Xu,W.Liu,X.Sun,Mater.Horiz 5(1)(2018)108-115.
[21]Y.Li,H.Zhang,M.Jiang,Q.Zhang,P.He,X.Sun,Adv.Funct.Mater 27(37)(2017)1702513.
[22]X.Peng,L.Wang,L.Hu,Y.Li,B.Gao,H.Song,C.Huang,X.Zhang,J.Fu,K.Huo,P.K.Chu,Nano Energy 34(2017)1-7.
[23]H.Li,P.Wen,Q.Li,C.Dun,J.Xing,C.Lu,S.Adhikari,L.Jiang,D.L.Carroll,S.M.Geyer,Adv.Energy Mater 7(17)(2017)1700513.
[24]J.Zheng,W.Zhou,T.Liu,S.Liu,C.Wang,L.Guo,Nanoscale 9(13)(2017)4409-4418.
[25]M.Gong,W.Zhou,M.-C.Tsai,J.Zhou,M.Guan,M.-C.Lin,B.Zhang,Y.Hu,D.-Y.Wang,J.Yang,S.J.Pennycook,B.-J.Hwang,H.Dai,Nat.Commun 5(2014)4695.
[26]Y.Wang,G.Zhang,W.Xu,P.Wan,Z.Lu,Y.Li,X.Sun,ChemElectroChem 1(7)(2014)1138-1144.
[27]Y.Ma,Z.He,Z.Wu,B.Zhang,Y.Zhang,S.Ding,C.Xiao,J.Mater.Chem.A 5(47)(2017)24850-24858.
[28]K.Hu,S.Jeong,M.Wakisaka,J.-i.Fujita,Y.Ito,Metals 8(2)(2018)83.
[29]M.Wu,S.Wang,J.Wang,Electrochim.Acta 258(2017)669-676.
[30]W.Lu,Y.Song,M.Dou,J.Ji,F.Wang,Chem.Commun 54(6)(2018)646-649.
[31]A.Wu,Y.Xie,H.Ma,C.Tian,Y.Gu,H.Yan,X.Zhang,G.Yang,H.Fu,Nano Energy 44(2018)353-363.
[32]X.Yin,G.Sun,A.Song,L.Wang,Y.Wang,H.Dong,G.Shao,Electrochim.Acta249(2017)52-63.
[33]Q.Zhang,P.Li,D.Zhou,Z.Chang,Y.Kuang,X.Sun,Small 13(41)(2017)1701648.
[34]Y.Huang,J.Ge,J.Hu,J.Zhang,J.Hao,Y.Wei,Adv.Energy Mater 8(6)(2017)1701601.
[35]R.Zhang,X.Wang,S.Yu,T.Wen,X.Zhu,F.Yang,X.Sun,X.Wang,W.Hu,Adv.Mater 29(9)(2017)1605502.
[36]T.Sun,J.Cao,J.Dong,H.Du,H.Zhang,J.Chen,L.Xu,Int.J.Hydrogen Energy42(10)(2017)6637-6645.
[37]L.Yu,H.Zhou,J.Sun,F.Qin,F.Yu,J.Bao,Y.Yu,S.Chen,Z.Ren,Energy Environ.Sci 10(8)(2017)1820-1827.
[38]S.F.Anis,B.S.Lalia,A.O.Mostafa,R.Hashaikeh,J.Mater.Sci 52(12)(2017)7269-7281.
[39]Y.Sun,L.Hang,Q.Shen,T.Zhang,H.Li,X.Zhang,X.Lyu,Y.Li,Nanoscale 9(43)(2017)16674-16679.
[40]Y.Zhang,Y.Liu,M.Ma,X.Ren,Z.Liu,G.Du,A.M.Asiri,X.Sun,Chem.Commun 53(80)(2017)11048-11051.
[41]J.Lin,C.Wang,S.Wang,Y.Chen,W.He,T.Ze,B.Chen,J.Alloys Compd 719(2017)376-382.
[42]Y.Qu,M.Yang,J.Chai,Z.Tang,M.Shao,C.T.Kwok,M.Yang,Z.Wang,D.Chua,S.Wang,Z.Lu,H.Pan,ACS Appl.Mater.Interfaces 9(7)(2017)5959-5967.
[43]F.Safizadeh,E.Ghali,G.Houlachi,Int.J.Hydrogen Energy 40(1)(2015)256-274.
[44]J.Guo,J.Wang,Z.Wu,W.Lei,J.Zhu,K.Xia,D.Wang,J.Mater.Chem.A 5(10)(2017)4879-4885.
[45]C.Wu,J.Li,ACS Appl.Mater.Interfaces 9(47)(2017)41314-41322.
[46]Y.Li,Z.Jiang,J.Huang,X.Zhang,J.Chen,Electrochim.Acta 249(2017)301-307.
[47]R.Solmaz,G.Karda?s,Electrochim.Acta 54(2009)3726-3734.
[48]M.I.Jamesh,P.Li,M.M.M.Bilek,R.L.Boxman,D.R.McKenzie,P.K.Chu,Corros.Sci 97(2015)126-138.
[49]M.I.Jamesh,G.Wu,Y.Zhao,W.Jin,D.R.McKenzie,M.M.M.Bilek,P.K.Chu,Corros.Sci 86(2014)239-251.
[50]M.Jamesh,T.S.N.Sankara Narayanan,P.K.Chu,Mater.Chem.Phys 138(2-3)(2013)565-572.
[51]M.I.Jamesh,G.Wu,Y.Zhao,D.R.McKenzie,M.M.M.Bilek,P.K.Chu,Corros.Sci 91(2015)160-184.
[52]M.Jamesh,S.Kumar,T.S.N.Sankara Narayanan,Corros.Sci 53(2011)645-654.
[53]P.Guo,J.Wu,X.-B.Li,J.Luo,W.-M.Lau,H.Liu,X.-L.Sun,L.-M.Liu,Nano Energy 47(2018)96-104.
[54]M.-S.Balogun,W.Qiu,Y.Huang,H.Yang,R.Xu,W.Zhao,G.-R.Li,H.Ji,Y.Tong,Adv.Mater 29(34)(2017)1702095.
[55]M.Tong,L.Wang,P.Yu,C.Tian,X.Liu,W.Zhou,H.Fu,ACS Sustain.Chem.Eng 6(2)(2018)2474-2481.
[56]Y.Jia,L.Zhang,G.Gao,H.Chen,B.Wang,J.Zhou,M.T.Soo,M.Hong,X.Yan,G.Qian,J.Zou,A.Du,X.Yao,Adv.Mater 29(17)(2017)1700017.
[57]J.Hou,Y.Sun,Y.Wu,S.Cao,L.Sun,Adv.Funct.Mater 28(4)(2018)1704447.
[58]N.Yabuuchi,K.Kubota,M.Dahbi,S.Komaba,Chem.Rev 114(23)(2014)11636-11682.
[59]M.Gong,D.Y.Wang,C.C.Chen,B.J.Hwang,H.Dai,Nano Res 9(1)(2016)28-46.
[60]S.A.Abbas,M.I.Iqbal,S.-H.Kim,K.-D.Jung,Electrochim.Acta 227(2017)382-390.
[61]L.Wang,Y.Li,M.Xia,Z.Li,Z.Chen,Z.Ma,X.Qin,G.Shao,J.Power Sources347(2017)220-228.
[62]L.Wang,Y.Li,X.Yin,Y.Wang,L.Lu,A.Song,M.Xia,Z.Li,X.Qin,G.Shao,Int.J.Hydrogen Energy 42(36)(2017)22655-22662.
[63]R.Karimi Shervedani,M.Torabi,F.Yaghoobi,Electrochim.Acta 244(2017)230-238.
[64]L.Wang,Y.Li,X.Yin,Y.Wang,A.Song,Z.Ma,X.Qin,G.Shao,ACS Sustain.Chem.Eng 5(9)(2017)7993-8003.
[65]B.Tian,J.Lei,J.Wang,ACS Appl.Mater.Interfaces 9(46)(2017)40162-40170.
[66]C.Yang,M.Y.Gao,Q.B.Zhang,J.R.Zeng,X.T.Li,A.P.Abbott,Nano Energy 36(2017)85-94.
[67]B.He,M.Zhou,Z.Hou,G.Li,Y.Kuang,J.Mater.Res 33(5)(2017)519-527.
[68]Q.Ma,C.Hu,K.Liu,S.-F.Hung,D.Ou,H.M.Chen,G.Fu,N.Zheng,Nano Energy 41(2017)148-153.
[69]T.Tian,L.Huang,L.Ai,J.Jiang,J.Mater.Chem.A 5(39)(2017)20985-20992.
[70]Z.Fang,Y.Wang,Y.Zou,Z.Hao,Q.Dong,Inorg.Chem.Commun 79(2017)1-4.
[71]H.Wang,Y.Xie,H.Cao,Y.Li,L.Li,Z.Xu,X.Wang,N.Xiong,K.Pan,ChemSus Chem 10(24)(2017)4899-4908.
[72]M.Gao,L.Chen,Z.Zhang,X.Sun,S.Zhang,J.Mater.Chem.A 6(3)(2018)833-836.
[73]J.Wang,S.Mao,Z.Liu,Z.Wei,H.Wang,Y.Chen,Y.Wang,ACS Appl.Mater.Interfaces 9(8)(2017)7139-7147.
[74]P.Guo,Y.-X.Wu,W.-M.Lau,H.Liu,L.-M.Liu,Int.J.Hydrogen Energy 42(44)(2017)26995-27003.
[75]X.Y.Yan,S.Devaramani,J.Chen,D.L.Shan,D.D.Qin,Q.Ma,X.Q.Lu,New J.Chem 41(6)(2017)2436-2442.
[76]K.Xu,H.Cheng,H.Lv,J.Wang,L.Liu,S.Liu,X.Wu,W.Chu,C.Wu,Y.Xie,Adv.Mater.30(1)(2018)1703322.
[77]L.Yao,N.Zhang,Y.Wang,Y.Ni,D.Yan,C.Hu,J.Power Sources 374(2018)142-148.
[78]X.X.Liu,J.B.Zang,L.Chen,L.B.Chen,X.Chen,P.Wu,S.Y.Zhou,Y.H.Wang,J.Mater.Chem.A 5(12)(2017)5865-5872.
[79]X.Zhang,X.Zhang,H.Xu,Z.Wu,H.Wang,Y.Liang,Adv.Funct.Mater 27(24)(2017)1606635.
[80]B.Luo,T.Huang,Y.Zhu,D.Wang,J.Energy Chem 26(6)(2017)1147-1152.
[81]Y.Pan,K.Sun,S.Liu,X.Cao,K.Wu,W.-C.Cheong,Z.Chen,Y.Wang,Y.Li,Y.Liu,D.Wang,Q.Peng,C.Chen,Y.Li,J.Am.Chem.Soc 140(7)(2018)2610-2618.
[82]C.Zhang,Z.Pu,I.S.Amiinu,Y.Zhao,J.Zhu,Y.Tang,S.Mu,Nanoscale 10(6)(2018)2902-2907.
[83]Z.Wang,H.Liu,R.Ge,X.Ren,J.Ren,D.Yang,L.Zhang,X.Sun,ACS Catal 8(3)(2018)2236-2241.
[84]Z.Xiao,Y.Wang,Y.-C.Huang,Z.Wei,C.-L.Dong,J.Ma,S.Shen,Y.Li,S.Wang,Energy Environ.Sci 10(12)(2017)2563-2569.
[85]C.Ray,S.C.Lee,B.Jin,A.Kundu,J.H.Park,S.C.Jun,J.Mater.Chem.A 6(10)(2018)4466-4476.
[86]S.Li,C.Yang,Z.Yin,H.Yang,Y.Chen,L.Lin,M.Li,W.Li,G.Hu,D.Ma,Nano Res 10(4)(2017)1322-1328.
[87]C.Zhu,A.-L.Wang,W.Xiao,D.Chao,X.Zhang,N.H.Tiep,S.Chen,J.Kang,X.Wang,J.Ding,J.Wang,H.Zhang,H.J.Fan,Adv.Mater 30(13)(2018)1705516.
[88]S.Huang,Y.Meng,S.He,A.Goswami,Q.Wu,J.Li,S.Tong,T.Asefa,M.Wu,Adv.Funct.Mater 27(17)(2017)1606585.
[89]L.Yan,L.Cao,P.Dai,X.Gu,D.Liu,L.Li,Y.Wang,X.Zhao,Adv.Funct.Mater27(40)(2017)1703455.
[90]L.Han,T.Yu,W.Lei,W.Liu,K.Feng,Y.Ding,G.Jiang,P.Xu,Z.Chen,J.Mater.Chem.A 5(32)(2017)16568-16572.
[91]S.Saha,K.Ojha,M.Sharma,A.K.Ganguli,New J.Chem 41(13)(2017)5916-5923.
[92]J.Deng,H.Zhang,Y.Zhang,P.Luo,L.Liu,Y.Wang,J.Power Sources 372(2017)46-53.
[93]J.Yin,Y.Li,F.Lv,M.Lu,K.Sun,W.Wang,L.Wang,F.Cheng,Y.Li,P.Xi,S.Guo,Adv.Mater 29(47)(2017)1704681.
[94]L.Chen,J.Zhang,X.Ren,R.Ge,W.Teng,X.Sun,X.Li,Nanoscale 9(43)(2017)16632-16637.
[95]Z.Liu,H.Tan,J.Xin,J.Duan,X.Su,P.Hao,J.Xie,J.Zhan,J.Zhang,J.-J.Wang,H.Liu,ACS Appl.Mater.Interfaces 10(4)(2018)3699-3706.
[96]Y.Gu,S.Chen,J.Ren,Y.A.Jia,C.Chen,S.Komarneni,D.Yang,X.Yao,ACSNano 12(1)(2018)245-253.
[97]H.Zhang,X.Li,A.H?hnel,V.Naumann,C.Lin,S.Azimi,S.L.Schweizer,A.W.Maijenburg,R.B.Wehrspohn,Adv.Funct.Mater 28(14)(2018)1706847.
[98]X.Zhang,S.Zhu,L.Xia,C.Si,F.Qu,F.Qu,Chem.Commun 54(10)(2018)1201-1204.
[99]Z.Wu,X.Wang,J.Huang,F.Gao,J.Mater.Chem.A 6(1)(2018)167-178.
[100]H.Begum,S.Jeon,Int.J.Hydrogen Energy 43(11)(2018)5522-5529.
[101]Z.Wu,Z.Wang,F.Geng,ACS Appl.Mater.Interfaces 10(10)(2018)8585-8593.
[102]Y.Shen,Y.Zhou,D.Wang,X.Wu,J.Li,J.Xi,Adv.Energy Mater 8(2)(2018)1701759.
[103]J.Zheng,X.Chen,X.Zhong,S.Li,T.Liu,G.Zhuang,X.Li,S.Deng,D.Mei,J.G.Wang,Adv.Funct.Mater 27(46)(2017)1704169.
[104]Y.Lv,Z.Chen,Y.Liu,T.Wang,Z.Ming,Nano Struct.Nano Objects 15(2018)114-118.
[105]B.Ren,D.Li,Q.Jin,H.Cui,C.Wang,J.Mater.Chem.A 5(36)(2017)19072-19078.
[106]L.Wu,Z.Pu,Z.Tu,I.S.Amiinu,S.Liu,P.Wang,S.Mu,Chem.Eng.J 327(2017)705-712.
[107]L.Huo,B.Liu,Z.Gao,J.Zhang,J.Mater.Chem.A 5(35)(2017)18494-18501.
[108]R.S.Datta,F.Haque,M.Mohiuddin,B.J.Carey,N.Syed,A.Zavabeti,B.Zhang,H.Khan,K.J.Berean,J.Z.Ou,N.Mahmood,T.Daeneke,K.Kalantar-zadeh,J.Mater.Chem.A 5(46)(2017)24223-24231.
[109]J.Zhao,X.Ren,H.Ma,X.Sun,Y.Zhang,T.Yan,Q.Wei,D.Wu,ACS Sustain.Chem.Eng 5(11)(2017)10093-10098.
[110]J.Xiao,Y.Zhang,Z.Zhang,Q.Lv,F.Jing,K.Chi,S.Wang,ACS Appl.Mater.Interfaces 9(27)(2017)22604-22611.
[111]M.A.R.Anjum,M.H.Lee,J.S.Lee,J.Mater.Chem.A 5(25)(2017)13122-13129.
[112]Y.Zhang,X.Xia,X.Cao,B.Zhang,N.H.Tiep,H.He,S.Chen,Y.Huang,H.J.Fan,Adv.Energy Mater 7(15)(2017)1700220.
[113]X.Zhang,X.Yu,L.Zhang,F.Zhou,Y.Liang,R.Wang,Adv.Funct.Mater 28(16)(2018)1706523.
[114]M.A.R.Anjum,J.S.Lee,ACS Catal 7(4)(2017)3030-3038.
[115]W.Gao,W.Gou,X.Zhou,J.C.Ho,Y.Ma,Y.Qu,ACS Appl.Mater.Interfaces 10(2)(2018)1728-1733.
[116]W.Wang,L.Yang,F.Qu,Z.Liu,G.Du,A.M.Asiri,Y.Yao,L.Chen,X.Sun,J.Mater.Chem.A 5(32)(2017)16585-16589.
[117]X.Zhang,Y.Liang,Adv.Sci 5(2)(2018)1700644.
[118]F.Wang,Y.Sun,Y.He,L.Liu,J.Xu,X.Zhao,G.Yin,L.Zhang,S.Li,Q.Mao,Y.Huang,T.Zhang,B.Liu,Nano Energy 37(2017)1-6.
[119]Y.Ge,S.-P.Gao,P.Dong,R.Baines,P.M.Ajayan,M.Ye,J.Shen,Nanoscale 9(17)(2017)5538-5544.
[120]L.Fang,W.Li,Y.Guan,Y.Feng,H.Zhang,S.Wang,Y.Wang,Adv.Funct.Mater27(24)(2017)1701008.
[121]C.Hu,L.Zhang,Z.-J.Zhao,A.Li,X.Chang,J.Gong,Adv.Mater 30(12)(2018)1705538.
[122]S.Zhang,X.Zhang,J.Li,E.Wang,J.Mater.Chem.A 5(39)(2017)20588-20593.
[123]C.Wang,P.Zhang,J.Lei,W.Dong,J.Wang,Electrochim.Acta 246(2017)712-719.
[124]B.Xu,H.Yang,L.Yuan,Y.Sun,Z.Chen,C.Li,J.Power Sources 366(2017)193-199.
[125]Y.Zhao,C.Chang,F.Teng,Y.Zhao,G.Chen,R.Shi,G.I.N.Waterhouse,W.Huang,T.Zhang,Adv.Energy Mater 7(18)(2017)1700005.
[126]B.Zhang,G.Yang,C.Li,K.Huang,J.Wu,S.Hao,J.Feng,D.Peng,Y.Huang,Nanoscale 10(4)(2018)1774-1778.
[127]H.Liu,Q.He,H.Jiang,Y.Lin,Y.Zhang,M.Habib,S.Chen,L.Song,ACS Nano11(11)(2017)11574-11583.
[128]K.Qu,Y.Zheng,X.Zhang,K.Davey,S.Dai,S.Z.Qiao,ACS Nano 11(7)(2017)7293-7300.
[129]H.Li,X.Qian,C.Xu,S.Huang,C.Zhu,X.Jiang,L.Shao,L.Hou,ACS Appl.Mater.Interfaces 9(34)(2017)28394-28405.
[130]Y.Wang,S.Zhu,N.Tsubaki,M.Wu,Chem Cat Chem 10(10)(2018)2300-2304.
[131]G.Yan,X.Feng,S.U.Khan,L.Xiao,W.Xi,H.Tan,Y.Ma,L.Zhang,Y.Li,Chem.Asian J 13(2)(2018)158-163.
[132]G.Zhi,B.Liu,S.Wang,L.Huo,Z.Gao,J.Zhang,Electrochim.Acta 258(2017)970-978.
[133]W.Chen,J.Pei,C.-T.He,J.Wan,H.Ren,Y.Zhu,Y.Wang,J.Dong,S.Tian,W.-C.Cheong,S.Lu,L.Zheng,X.Zheng,W.Yan,Z.Zhuang,C.Chen,Q.Peng,D.Wang,Y.Li,Angew.Chem.Int.Ed 56(50)(2017)16086-16090.
[134]D.Gao,J.Guo,X.Cui,L.Yang,Y.Yang,H.He,P.Xiao,Y.Zhang,ACS Appl.Mater.Interfaces 9(27)(2017)22420-22431.
[135]J.Xiong,W.Cai,W.Shi,X.Zhang,J.Li,Z.Yang,L.Feng,H.Cheng,J.Mater.Chem.A 5(46)(2017)24193-24198.
[136]C.Wang,B.Tian,M.Wu,J.Wang,ACS Appl.Mater.Interfaces 9(8)(2017)7084-7090.
[137]T.Meng,L.Zheng,J.Qin,D.Zhao,M.Cao,J.Mater.Chem.A 5(38)(2017)20228-20238.
[138]X.Sun,J.Huo,Y.Yang,L.Xu,S.Wang,J.Energy Chem 26(6)(2017)1136-1139.
[139]S.Jing,L.Zhang,L.Luo,J.Lu,S.Yin,P.K.Shen,P.Tsiakaras,Appl.Catal.,B 224(2018)533-540.
[140]Z.Lu,W.Zhu,X.Yu,H.Zhang,Y.Li,X.Sun,X.Wang,H.Wang,J.Wang,J.Luo,X.Lei,L.Jiang,Adv.Mater 26(17)(2014)2683-2687.
[141]W.Xu,Z.Lu,X.Sun,L.Jiang,X.Duan,Accounts Chem.Res 51(7)(2018)1590-1598.
[142]Z.Lu,Y.Li,X.Lei,J.Liu,X.Sun,Mater.Horiz 2(3)(2015)294-298.
[143]B.E.Conway,G.Jerkiewicz,Electrochim.Acta 45(25)(2000)4075-4083.
[144]W.Sheng,H.A.Gasteiger,Y.Shao-Horn,J.Electrochem.Soc 157(11)(2010)B1529-B1536.