申雪然, 冯彩虹, 代政, 赵芸, 矫庆泽 . 电解海水制氢的研究进展[J]. 化工新型材料, 2021 , 49(12) : 55 -60 . DOI: 10.19817/j.cnki.issn 1006-3536.2021.12.012

[1] Turner J A.Sustainable hydrogen production[J].Science,2004,305:972-974.
[2] 刘太楷,邓春明,张亚鹏.电解水制氢发展概况之一:碱式电解水[J].材料研究与应用,2019,13(4):339-346.
[3] Landman A,Dotan H,Shter G E,et al.Photoelectrochemical water splitting in separate oxygen and hydrogen cells[J].Nature Materials,2017,16(6):646-651.
[4] Amikam G,Nativ P,Gendel Y.Chlorine-free alkaline seawater electrolysis for hydrogen production[J].International Journal of Hydrogen Energy,2018,43:6504-6514.
[5] Song H J,Yoon H,Ju B,et al.Electrocatalytic selective oxygen evolution of carbon-coated Na₂Co_1-xFe_xP₂O₇ nanoparticles for alkaline seawater electrolysis[J].ACS Catalysis,2020,10:702-709.
[6] 李永恒,陈洁,刘城市,等.氢气制备技术的研究进展[J].电镀与精饰,2019,41(10):22-27.
[7] Zhou H Q,Yu F,Zhu Q,et al.Water splitting by electrolysis at high current densities under 1.6 volts[J].Energy & Environmental Science,2018,10:2858-2864.
[8] Abdel-Aal H K,Zohdy K M,Abdel K M.Hydrogen production using sea water electrolysis[J].The Open Fuel Cells Journal,2010,3:1-7.
[9] Cuartero M,Crespo G,Cherubini T,et al.In situ detection of macronutrients and chloride in seawater by submersible electrochemical sensors[J].Analytical Chemistry,2018,90(7):4702-4710.
[10] Vos J G,Koper M T M.Measurement of competition between oxygen evolution and chlorine evolution using rotating ring-disk electrode voltammetry[J].Journal of Electroanalytical Chemistry,2018,819:260-268.
[11] Dionigi F,Reier T,Pawolek Z,et al.Design criteria,operating conditions,and nickel-iron hydroxide catalyst materials for selective seawater electrolysis[J].ChemSusChem,2016,9(9):962-972.
[12] Kuang Y,Kenney M J,Meng Y T,et al.Solar-driven,highly sustained splitting of seawater into hydrogen and oxygen fuels[J].PNAS,2019,116(14):6624-6629.
[13] Cheng F,Feng X,Chen X,et al.Synergistic action of Co-Fe layered double hydroxide electrocatalyst and multiple ions of sea salt for efficient seawater oxidation at near-neutral pH[J].Electrochimica Acta,2017,251:336-343.
[14] Lu X,Pan J,Lovell E,et al.A sea-change:manganese doped nickel/nickel oxide electrocatalysts for hydrogen generation from seawater[J].Energy & Environmental Science,2018,11(7):1898-1910.
[15] Williams L O.Electrolysis of sea water[J].Hydrogen Energy,1975,2:427-424.
[16] Bennett J E.Electrodes for generation of hydrogen and oxygen from seawater[J].International Journal of Hydrogen Energy,1980,5(4):401-408.
[17] Izumiya K,Akiyama E,Habazaki H,et al.Effects of additional elements on electrocatalytic properties of thermally decomposed manganese oxide electrodes for oxygen evolution from seawater[J].MaterialsTransactions Jim,1997,38(10):899-905.
[18] Fujimura K,Matsui T,Habazaki H,et al.The durability of manganese-molybdenum oxide anodes for oxygen evolution in seawater electrolysis[J].Electrochimica Acta,2000,45(14):2297-2303.
[19] Izumiya K,Akiyama E,Habazaki H,et al.Anodically deposited manganese oxide and manganese-tungsten oxide electrodes for oxygen evolution from seawater[J].Electrochimica Acta,1998,43(21-22):3303-3312.
[20] Habazaki H,Matsui T,Kawashima A,et al.Nanocrystalline manganese-molybdenum-tungsten oxide anodes for oxygen evolution in seawater electrolysis[J].Scripta Materialia,2001,44(8-9):1659-1662.
[21] Kato Z,Bhattarai J,Kumagai N,et al.Durability enhancement and degradation of oxygen evolution anodes in seawater electrolysis for hydrogen production[J].Applied Surface Science,2011,257(19):8230-8236.
[22] Abdel G N A,Kumagai N,Meguro S,et al.Oxygen evolution anodes composed of anodically deposited Mn-Mo-Fe oxides for seawater electrolysis[J].Electrochimica Acta,2002,48(1):21-28.
[23] Surendranath Y,Dincá M,Nocera D G.Electrolyte-dependent electrosynthesis and activity of cobalt-based water oxidation catalysts[J].Journal of the American Chemical Society,2009,131(7):2615-2620.
[24] Esswein A J,Surendranath Y,Reece S Y,et al.Highly active cobalt phosphate and borate based oxygen evolving catalysts operating in neutral and natural waters[J].Energy & Environmental Science,2011,4(2):499-504.
[25] Hsu S H,Miao J,Zhang L,et al.An earth-abundant catalyst-based seawater photoelectrolysis system with 17.9% solar-to-hydrogen efficiency[J].Advanced Materials,2018,30(18):1707261.
[26] Yu L,Zhu Q,Song S W,et al.Non-noble metal-nitride based electrocatalysts for high-performance alkaline seawater electrolysis[J].Nature Communications,2019,10:5106.
[27] Zhuang Z W,Wang Y,Xu C Q,et al.Three-dimensional open nano-netcage electrocatalysts for efficient pH-universal overall water splitting[J].Nature Communications,2019,10:4875.
[28] Jiang N,Meng H M,Song L J,et al.Study on Ni-Fe-C cathode for hydrogen evolution from seawater electrolysis[J].International Journal of Hydrogen Energy,2010,35:8056-8062.
[29] Gao S,Li G D,Liu Y,et al.Electrocatalytic H₂ production from seawater over Co,N-codoped nanocarbons[J].Nanoscale,2015,7(6):2306-2316.
[30] Martindale B C M,Reisner E.Bi-functional iron-only electrodes for efficient water splitting with enhanced stability through in situ electrochemical regeneration[J].Advanced Energy Materials,2016,6(6):1502095.
[31] Ma Y Y,Wu C X,Feng X J,et al.Highly efficient hydrogen evolution from seawater by a low-cost and stable CoMoP@C electrocatalyst superior to Pt/C[J].Energy & Environmental Science,2017,10(3):788-798.
[32] Ham D J,Lee J S.Transition metal carbides and nitrides as electrode materials for low temperature fuel cells[J].Energies,2009,2:873-899.
[33] Zhong Y,Xia X H,Shi F,et al.Transition metal carbides and nitrides in energy storage and conversion[J].Advanced Science,2016,3:1500286.
[34] Peng X,Pi C R,Zhang X M,et al.Recent progress of transition metal nitrides for efficient electrocatalytic water splitting[J].Sustainable Energy Fuels,2019,3:366-381.
[35] Wei B B,Tang G S,Liang H F,et al.Bimetallic vanadium-molybdenum nitrides using magnetron co-sputtering as alkaline hydrogen evolution catalyst[J].Electrochemistry Communications,2018,98:166-170.
[36] Jin H Y,Liu X,Vasileff A,et al.Single-crystal nitrogen-rich two-dimensional Mo₅N₆ nanosheets for efficient and stable seawater splitting[J].ACS Nano,2018,12:12761-12769.
[37] Zhao Y Q,Jin B,Zheng Y,et al.Charge state manipulation of cobalt selenide catalyst for overall seawater electrolysis[J].Advanced Energy Materials,2018,8(29):1801926.
[38] Zhao Y Q,Jin B,Vasileff A,et al.Interfacial nickel nitride/sulfide as a bifunctional electrode for highly efficient overall water/seawater electrolysis[J].Journal of Materials Chemistry A,2019,7:8117-8121.
[39] Lv Q L,Han J X,Tan X L,et al.Featherlike NiCoP holey nanoarrys for efficient and stable seawater splitting[J].ACS Applied Energy Materials,2019,2:3910-3917.
[40] Liu Y C,Hu X,Huang B B,et al.Surface engineering of Rh catalysts with N/S-codoped carbon nanosheets toward high-performance hydrogen evolution from seawater[J].ACS Sustainable Chemistry & Engineering,2019,7:18835-18843.