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固体氧化物燃料电池(SOFC)的阳极在使用含硫廉价燃料时极易发生硫中毒现象,导致电池性能迅速衰退。本综述在介绍SOFC电极反应机制的基础上,结合近些年的文献,对不同材料的阳极硫中毒现象进行了汇总,分析了阳极硫毒化和活化规律,深入探究了硫中毒物理与化学机制,总结了硫中毒阳极的再生及活化新方法,并分析了相关再生机制。
Abstract:The anode of SOFC is easy to react with sulfur impurities in the cheap hydrocarbon and carbonaceous fuels, which lead to the loss of the SOFC electrochemical performance. This review introduces the electrode reaction mechanism of the SOFC and analysis the rule of the anode sulfur poisoning and activation on the basis of the literature in recent years, in addition, the physical and chemical mechanism of the sulfur poisoning are summarized and some new regeneration methods are also summarized.
[1] SHU L N, SUNARSO J, HASHIM S S, et al. Advanced perovskite anodes for solid oxide fuel cells:A review[J]. Int J Hydrogen Energ,2019, 44(59):31275–31304.
[2] CAO Z Q, ZHANG Y H, MIAO J P, et al. Titanium-substituted lanthanum strontium ferrite as a novel electrode material for symmetrical solid oxide fuel cell[J]. Int J Hydrogen Energ, 2015, 40:16572–16577.
[3] LEI L B, KEELS J M, TAO Z T, et al. Thermodynamic and experimental assessment of proton conducting solid oxide fuel cells with internal methane steam reforming[J]. Appl Energ, 2018, 224:280–288.
[4] SURANAT W, HIROSHI I, MOTOHIRO S, et al. Performance evaluation of a direct-biogas solid oxide fuel cell-micro gas turbine(SOFC-MGT)hybrid combined heat and power(CHP)system[J]. J Power Sources, 2013, 223:9–17.
[5] PELLEGRINOS, LANZINI A, LEONE P. Techno-economic and policy requirements for the market-entry of the fuel cell micro-CHP system in the residential sector[J]. Appl Energ, 2015, 143:370–382.
[6] NAPOLI R, GANDIGLIO M, LANZINI A, et al. Techno-economic analysis of PEMFC and SOFC micro-CHP fuel cells systems for the residential sector[J]. Energ Build, 2015, 103:131–146.
[7] FRENZEL I, LOUKOU A, TRIMIS D, et al. Development of an SOFC based micro-CHP system in the framework of the European project FC-DISTRICT[J]. Energ Proc, 2012, 28:170–181.
[8] BARELLI L, BIDINI G, GALLORINI F, et al. Design optimization of a SOFC-based CHP system through dynamic analysis[J]. Int J Hydrogen Energ, 2013, 38(1):354–369.
[9] NAIMASTER E J, SLEITI A K. Potential of SOFC CHP systems for energy-efficient commercial buildings[J]. Energ Build, 2013, 61:153–160.
[10] SINGHAL S C. Solid oxide fuel cells for stationary, mobile, and military applications[J]. Solid State Ionics, 2002, 152–153:405–410.
[11] MADI H, DIETHELM S, VAN J. Effect of steam-to-carbon ratio on degradation of Ni-YSZ anode supported cells[J]. ECS Trans, 2013,57(1):1517–1525.
[12] CRLETTI F, GANDIGLIO M, A. LANZINI A, et al. Large size biogas-fed solid oxide fuel cell power plants with carbon dioxide management:Technical and economic optimization[J]. J Power Sources, 2015, 294:669–690.
[13] PAPADIAS DD, AHMED S, KUMAR R. Fuel quality issues with biogas energy—An economic analysis for a stationary fuel cell system[J]. Energy, 2012, 44(1):257–277.
[14] LANZINI A, LEONE P, GUERRA C, et al. Durability of anode supported solid oxides fuel cells(SOFC)under direct dry-reforming of methane[J]. Chem Eng J, 2013, 220:254–263.
[15] RESTREPO V A, HILL J M. Carbon deposition on Ni/YSZ anodes exposed to CO/H2 feeds[J]. J Power Sources, 2010, 195(5):1344–1351.
[16] FARRELLl B, LINIC S. Direct electrochemical oxidation of ethanol on SOFCs:improved carbon tolerance of Ni anode by alloying[J]. Appl Catal B:Environ, 2016, 183:386–393.
[17] PAPURELLO D, LANZINI A, FIORILLI S, et al. Sulfur poisoning in Ni-anode solid oxide fuel cells(SOFCs):Deactivation in single cells and a stack[J]. Chem Eng J, 2016, 283:1224–1233.
[18] CHENG Z, ZHA S W, LIU M L. Influence of cell voltage and current on sulfur poisoning behavior of solid oxide fuel cells[J]. J Power Sources, 2007, 172(2):688–693.
[19] CHENG Z, LIU M L. Characterization of sulfur poisoning of Ni–YSZ anodes for solid oxide fuel cells using in situ Raman microspectroscopy[J]. Solid State Ionics, 2007, 178(13–14):925–935.
[20] JIANG S P. Activation, microstructure, and polarization of solid oxide fuel cell cathodes[J]. J Solid State Electrochem, 2006, 11(1):93–102.
[21] LANZINI A, MADI H, PAPURELLO D, et al. Dealing with fuel contaminants in biogas-fed solid oxide fuel cell(SOFC)and molten carbonate fuel cell(MCFC)plants:degradation of catalytic and electro-catalytic active surfaces and related gas purification methods[J].Prog Energy Combust, 2017, 61:150–188.
[22] GONG M, LIU X, TREMBLY J, et al. Sulfur-tolerant anode materials for solid oxide fuel cell application[J]. J Power Sources, 2007, 168:289–298.
[23] PETER M K. Energy production from biomass(part 1):Overview of biomass[J]. Bioresource Technol, 2002, 83(1):37–46.
[24] PETERSON D R, WINNICK J. Utilization of hydrogen sulfide in an intermediate-temperature ceria-based solid oxide fuel cell[J]. J Electrochem Soc, 1998, 145:1449–1454.
[25] YENTEKAKIS I, VAYENAS C. Chemical cogeneration in solid electrolyte cells:the oxidation of H2S to SO2[J]. J Electrochem Soc,1989, 136:996–1002.
[26] SASAKI K, SUSUKI K, IYOSHI A, et al. H2S poisoning of solid oxide fuel cells[J]. J Electrochem Soc, 2006, 153(31):A2023–A2027.
[27] PUJARE N U, SEMKOW K W, SAMMELLS A F. A direct H2S/Air solid oxide fuel cell[J]. J Electrochem Soc, 1987, 134:2639–2640.
[28] LIU M, HE P, LUO J, et al. Performance of a solid oxide fuel cell utilizing hydrogen sulfide as fuel[J]. J Power Sources, 2001, 94:20–25.
[29] ZHA S, CHENG Z, LIU M. Sulfur poisoning and regeneration of Ni-based anodes in solid oxide fuel cells[J]. J Electrochem Soc, 2007,54:B201–B206.
[30] CHENG Z, WANG J H, CHOI Y M, et al. From Ni-YSZ to sulfur-tolerant anode materials for SOFCs:Electrochemical[J]. Energ Environ Sci, 2011, 4:4380–4409.
[31] MATSUZAKI Y, YASUDA I. The poisoning effect of sulfur-containing impurity gas on a SOFC anode:Part I. Dependence on temperature,time, and impurity concentration[J]. Solid State Ionics, 2000, 132:261–269.
[32] CHENG Z. Investigations into the interactions between sulfur and anodes for solid oxide fuel cells(dissertation). Georgia State:Georgia Institute of Technology, 2008:92.
[33] CHENG Z, ZHA S, LIU M. Influence of cell voltage and current on sulfur poisoning behavior of solid oxide fuel cells[J]. J Power Sources,2007, 172:688–693.
[34] LI T S, WANG W G. The mechanism of H2S poisoning Ni/YSZ electrode studied by impedance spectroscopy[J]. Electrochem Solid-State Lett, 2011, 14(3):B35–B37.
[35] LI T S, WANG W G. Sulfur-poisoned Ni-based solid oxide fuel cell anode characterization by varying water content[J]. J Power Sources,2011, 196:2066–2069.
[36] SINGHAL S C, RUKA R J, BAUERLE J E, et al. Anode development for solid oxide fuel cells. Final technical report[R]. The Department of Energy DOE/MC/22046-2371(NITS Order No. DE87011136),Pittsburgh, 1986.
[37] MUNKUNDAN R, BROSHA E L, GARZON F H. Sulfur tolerant anodes for SOFCs[J]. Electrochem Solid-State Lett, 2004, 7(1):A5–A7.
[38] VINCENT A L, LUO J L, CHUANG K T, et al. Promotion of activation of CH4 by H2S in oxidation of sour gas over sulfur tolerant SOFC anode catalysts[J]. Appl Catal Environ, 2011, 106:114–122.
[39] MARINA O A, CANFIELD N L, STEVEVSON J W. Thermal,electrical, and electrocatalytical properties of lanthanum-doped strontium titanate[J]. Solid State Ionics, 2002, 149:21–28.
[40] ROUSHANAFSHAR M, YAN N, CHUANG K T, et al.Electrochemical oxidation of sour natural gas over La0.4Ce0.6O1.8-La0.4Sr0.6TiO3±δanode in SOFC:A mechanism study of H2S effects[J]. Appl Catal Environ, 2015, 176/177:627–636.
[41] ROUSHANAFSHAR M, LUO J L, VINCENT A L, et al. Effect of hydrogen sulfide inclusion in syngas feed on the electrocatalytic activity of LST-YDC composite anodes for high temperature SOFC applications[J]. Int J Hydrogen Energ, 2012, 37:7762–7770.
[42] VINCENT A L, LUO J L, CHUANG K T, et al. Effect of Ba doping on performance of LST as anode in solid oxide fuel cells[J]. J Power Sources, 2010, 195:769–774.
[43] AGUILAR L, et al. A solid oxide fuel cell operating on hydrogen sulfide(H2S)and sulfur-containing fuels[J]. J Power Sources, 2004,135(1):17–24.
[44] AGUILAR L, ZHA S W. LI S W, et al. Sulfur-tolerant materials for the hydrogen sulfide SOFC[J]. Electrochem Solid-State Lett, 2004, 7:A324–A326.
[45] CHENG Z, ZHA S W, AGUILAR L, et al. A solid oxide fuel cell running on H2S/CH4 fuel mixtures[J]. Electrochem Solid-State Lett,2006, 9(1):A31–A33.
[46] TREMBLY J P, MARQUEZ A I, OHRN T R, et al. Effects of coal syngas and H2S on the performance of solid oxide fuel cells:Single-cell tests[J]. J Power Sources, 2006, 158:263–273.
[47] LI M, HUA B, JIANG S P, et al. BaZr0.1Ce0.7Y0.1Yb0.1O3–δas highly active and carbon tolerant anode for direct hydrocarbon solid oxide fuel cells[J]. Int J Hydrogen Energ, 2014, 39:15975–15981.
[48] YANG L, WANG S Z, BLINN K, et al. Enhanced sulfur and coking tolerance of a mixed ion conductor for SOFCs:BaZr0.1Ce0.7Y0.2–x Ybx O3–δ[J]. Science, 2009, 326:126–129.
[49] HUA B, YAN N, LI M, et al. Anode-engineered protonic ceramic fuel cell with excellent performance and fuel compatibility[J]. Adv Mater,2016, 28:8922–8926.
[50] ZHA S W, TSANG P, CHENG Z, et al. Electrical properties and sulfur tolerance of La0.75Sr0.25Cr1–x Mnx O3 under anodic conditions[J]. J Solid State Electrochem, 2005, 178:1844–1850.
[51] CHEN X J, LIU Q L, CHAN S H, et al. Sulfur tolerance and hydrocarbon stability of La0.75Sr0.25Cr0.5Mn0.5O3/Gd0.2Ce0.8O1.9composite anode under anodic polarization[J]. J Electrochem Soc,2007, 54(11):B1206–B1210.
[52] LI Y Q, ZHANG Y H, ZHU X B, et al. Performance and sulfur poisoning of Ni/CeO2 impregnated La0.75Sr0.25Cr0.5Mn0.5O3-δanode in solid oxide fuel cells[J]. J Power Sources, 2015, 285:354–359.
[53] LI Y Q, NA L Y, LV Z, et al. Sulfur poisoning and the regeneration of the solid oxide fuel cell with metal catalyst-impregnated La0.75Sr0.25Cr0.5Mn0.5O3–δanode[J]. Int J Hydrogen Energ, 2020, 45:15650–15657.
[54] JI Y, HUANG Y H, YING J R, et al. Electrochemical performance of La-doped Sr2Mg MoO6–δin natural gas[J]. Electrochem Commun, 2007,9:1881–1885.
[55] WANG F Y, ZHONG J B, LUO S J, et al. Porous Sr2MgMo1–x Vx O6–δceramics as anode materials for SOFCs using biogas fuel[J]. Catal Commun, 2015, 67:108–111.
[56] ESCUDERO M J, GOMEZ DE PARADA I, FUERTE A, et al. Study of Sr2Mg(Mo0.8Nb0.2)O6–δas anode material for solid oxide fuel cells using hydrocarbons as fuel[J]. J Power Sources, 2013, 243:654–660.
[57] JIA L C, WANG X, HUA B, et al. Computational analysis of atomic C and S adsorption on Ni, Cu, and Ni-Cu SOFC anode surfaces[J]. Int J Hydrogen Energ, 2012, 37:11941–11945.
[58] WALKER E, AMMAL S C, SUTHIRAKUN S, et al. Mechanism of sulfur poisoning of Sr2Fe1.5Mo0.5O6–δperovskite anode under solid oxide fuel cell conditions[J]. J Phys Chem C, 2014, 118:23545–23552.
[59] HAN Z Y, WANG Y H, YANG Y R, et al. High performance SOFCs with impregnated Sr2Fe1.5Mo0.5O6–δanodes toward sulfur resistance[J].J Alloy Compd, 2017, 703:258–263.
[60] XIAO G L, LIU Q, DONG X H, et al. Sr2Fe4/3Mo2/3O6 as anodes for solid oxide fuel cells[J]. J Power Sources, 2010, 195:8071–8074.
[61] HUA B, LI M, SUN Y F, et al. Grafting doped manganite into nickel anode enables efficient and durable energy conversions in biogas solid oxide fuel cells[J]. Appl Catal Environ, 2017, 200:174–181.
[62] YAN N, ZANNA S, KLEIN L H, et al. The surface evolution of La0.4Sr0.6TiO3+δanode in solid oxide fuel cells:Understanding the sulfur-promotion effect[J]. J Power Sources, 2017, 343:127–134.
[63] LI J, WEI B, Yue X, et al. Investigations on sulfur poisoning mechanisms of a solid oxide fuel cell with niobium-doped ferrate perovskite anode[J]. Electrochimi Acta, 2020, 335:135703.
[64] SHIRATORI Y, IJICHI T, OSHIMA T, et al. Internal reforming SOFC running on biogas[J]. Int J Hydrogen Energ, 2010, 35(15):7905–7912.
[65] HAGEN A, RASMUSSEN J F B, THYDEN K. Durability of solid oxide fuel cells using sulfur containing fuels[J]. J Power Sources, 2011,196(17):7271–7276.
[66] HAUCH A, HAGEN A, HJELM J, et al. Sulfur poisoning of SOFC anodes:effect of overpotential on long-term degradation[J]. J Electrochem Soc, 2014, 161(6):F734–F743.
[67] ZHANG L, JIANG S P, HE H Q, et al. A comparative study of H2S poisoning on electrode behavior of Ni/YSZ and Ni/GDC anodes of solid oxide fuel cells[J]. Int J Hydrogen Energ, 2010, 35(22):12359–12368.
[68] LI Y Q, NA L Y, LV Z, et al. Regeneration of sulfur poisoned La0.75Sr0.25Cr0.5Mn0.5O3-δanode of solid oxide fuel cell using electrochemical oxidative method[J]. Electrochim Acta, 2019, 304:342–349.
[69] LI Y Q, WANG Z H, LI J W, et al. Sulfur poisoning and attempt of oxidative regeneration of La0.75Sr0.25Cr0.5Mn0.5O3-δanode for solid oxide fuel cell[J]. J Alloy Compd, 2017, 698:794–799.
基本信息:
DOI:10.14062/j.issn.0454-5648.20200455
中图分类号:TB34;TM911.4
引用信息:
[1]李一倩,李敬威,吕喆.固体氧化物燃料电池阳极的硫毒化与再生活化[J].硅酸盐学报,2021,49(01):126-135.DOI:10.14062/j.issn.0454-5648.20200455.
基金信息:
国家自然基金(51372057,51872067,51802086); 黑龙江省自然科学基金(LH2020E104)