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可逆固体氧化物电池(RSOC)是一种全固态电化学能量转换装置,可以实现化学能和电能的高效洁净可逆转换,有望应用于智能电网领域实现削峰填谷以及规模化可再生能源的转化存储。由于RSOC需要分别在固体氧化物燃料电池(SOFC)及固体氧化物电解池(SOEC)模式下进行可逆、循环切换工作(存在放电/供电及氧化/还原气氛变化),对电极材料性能和物理化学稳定性要求高,迫切需要提高电极催化活性和氧化还原稳定性。介绍了RSOC的工作原理,综述了目前RSOC电极材料的研究成果及研究现状,分析了可逆对称电极材料在RSOC中的应用前景并展望了其未来的发展方向。
Abstract:The reversible solid oxide cell(RSOC) is an all-solid-state electrochemical energy conversion device that can achieve an efficient and clean reversible conversion of chemical energy and electrical energy. In anticipation, the RSOCs can be applied in the field of the intelligent electric grid for peak shaving, as well as the conversion and storage of large-scale renewable energy. As the key components of RSOCs, the electrode materials are expected to exhibit great performance and stability since the RSOC works in a reversible cycle both in solid oxide fuel cell(SOFC) and solid oxide electrolysis cell(SOEC) modes. There is an impetration to improve the catalytic activity and the redox stability of electrode materials. This paper briefly introduced the working principles of RSOCs, discussed the recent progress of electrode materials for RSOCs and the application of symmetrical electrode materials and prospected the future development direction for RSOC.
[1] H??K M, TANG X. Depletion of fossil fuels and anthropogenic climate change—A review[J]. Energ Policy, 2013, 52:797–809.
[2] QUADRELLI R, PETERSON S. The energy–climate challenge:Recent trends in CO2 emissions from fuel combustion[J]. Energ Policy,2007, 35(11):5938–5952.
[3] PANWAR N L, KAUSHIK S C, KOTHARI S. Role of renewable energy sources in environmental protection:A review[J]. Renew Sust Energ Rev, 2011, 15(3):1513–1524.
[4] WANG L. Causes of and solutions to overcapacity in the new energy industry:Taking wind energy and solar energy as examples[J]. Chin J Urb Environ Stud, 2017, 5(1):1750005.
[5] ZENG M, DUAN J, WANG L, et al. Orderly grid connection of renewable energy generation in China:Management mode, existing problems and solutions[J]. Renew Sust Energ Rev, 2015, 41:14–28.
[6] NAWAZ M K, ZAFAR S. Integration of renewable energy sources in smart grid:A Review[J]. Nucleus, 2013, 50(4):311–327.
[7] DUNN B, KAMATH H, TARASCON J M. Electrical energy storage for the grid:A battery of choices[J]. Science, 2011, 334(6058):928–935.
[8] DI GIORGIO P, DESIDERI U. Potential of reversible solid oxide cells as electricity storage system[J]. Energies, 2016, 9(8):662.
[9] WENDEL C H, BRAUN R J. Design and techno-economic analysis of high efficiency reversible solid oxide cell systems for distributed energy storage[J]. Appl Energ, 2016, 172:118–131.
[10] YILDIZ B. Reversible solid oxide electrolytic cells for large-scale energy storage:challenges and opportunities[C]//Kilner J ed.Functional Materials for Sustainable Energy Applications. Oxford, UK:GlyndwrUniversity and Peter Edwards, University of Oxford, 2012:149–178,179.
[11] VENKATARAMAN V, PéREZ-FORTES M, WANG L, et al.Reversible solid oxide systems for energy and chemical applications—review&perspectives[J]. J Energy Storage, 2019, 24:100782.
[12] JENSEN S H, GRAVES C, MOGENSEN M, et al. Large-scale electricity storage utilizing reversible solid oxide cells combined with underground storage of CO2 and CH4[J]. Energy Environ Sci, 2015,8(8):2471–2479.
[13] YANG Z, ZHANG J, KINTNER-MEYER M C, et al. Electrochemical energy storage for green grid[J]. Chem Rev, 2011, 111(5):3577–3613.
[14] WANG W. The effect of internal air bleed on CO poisoning in a proton exchange membrane fuel cell[J]. J Power Sources, 2009, 191(2):400–406.
[15] DODDATHIMMAIAH A, ANDREWS J. Theory, modelling and performance measurement of unitised regenerative fuel cells[J]. Int J Hydrogen Energy 2009, 34(19):8157–8170.
[16] Stephen R. Reversible solid oxide fuel cells as energy conversion and storage devices(dissertation). St Andrews:University of St Andrews,2011.
[17] ZHONGLIANG, ZHAN, WORAWARIT, et al. Syngas production by coelectrolysis of CO2/H2O:The basis for a renewable energy cycle[J].Energ Fuel, 2009, 23(6):3089–3096.
[18] GRAVES C, EBBESEN S D, JENSEN S H, et al. Eliminating degradation in solid oxide electrochemical cells by reversible operation[J]. Nat Mater, 2014, 14(2):239–244.
[19] WENDEL C H, GAO Z, BARNETT S A, et al. Modeling and experimental performance of an intermediate temperature reversible solid oxide cell for high-efficiency, distributed-scale electrical energy storage[J]. J Power Sources, 2015, 283:329–342.
[20] BOLAT P, THIEL C. Hydrogen supply chain architecture for bottom-up energy systems models. Part 1:Developing pathways[J]. Int J Hydrogen Energ, 2014, 39(17):8881–8897.
[21] BOLAT P, THIEL C. Hydrogen supply chain architecture for bottom-up energy systems models. Part 2:Techno-economic inputs for hydrogen production pathways[J]. Int J Hydrogen Energ, 2014, 39(22):8898–8925.
[22] WANG Y, LIU T, LEI L, et al. High temperature solid oxide H2O/CO2co-electrolysis for syngas production[J]. Fuel Process Technol, 2017,161:248–258.
[23] ZHAN Z, ZHAO L. Electrochemical reduction of CO2 in solid oxide electrolysis cells[J]. J Power Sources, 2010, 195(21):7250–7254.
[24] TORRELL M, GARCíA-RODRíGUEZ S, MORATA A, et al.Co-electrolysis of steam and CO2 in full-ceramic symmetrical SOECs:a strategy for avoiding the use of hydrogen as a safe gas[J]. Faraday Discuss, 2015, 182:241–255.
[25] GOMEZ S Y, HOTZA D. Current developments in reversible solid oxide fuel cells[J]. Renew Sust Energ Rev, 2016, 61:155–174.
[26] PAN W, CHEN K, AI N, et al. Mechanism and kinetics of Ni-Y2O3-ZrO2 hydrogen electrode for water electrolysis reactions in solid oxide electrolysis cells[J]. J Electrochem Soc, 2015, 163(2):F106–F114.
[27] OSINKIN D A, BOGDANOVICH N M, BERESNEV S M, et al.Reversible solid oxide fuel cell for power accumulation and generation[J]. Russ J Electrochem, 2018, 54(8):644–649.
[28] SHRI PRAKASH B, SENTHIL KUMAR S, ARUNA S T. Properties and development of Ni/YSZ as an anode material in solid oxide fuel cell:A review[J]. Renew Sust Energ Rev, 2014, 36:149–179.
[29] LI Q, ZHENG Y, GUAN W, et al. Achieving high-efficiency hydrogen production using planar solid-oxide electrolysis stacks[J]. Int J Hydrogen Energ, 2014, 39(21):10833–10842.
[30] MENG X, LIU Y, YANG N, et al. Highly compact and robust hollow fiber solid oxide cells for flexible power generation and gas production[J]. Appl Energy, 2017, 205:741–748.
[31] JIAO Y, WANG L, ZHANG L, et al. Direct Operation of solid oxide fuel cells on low-concentration oxygen-bearing coal-bed methane with high stability[J]. Energ Fuel, 2018, 32(4):4547–4558.
[32] SILVA A L D, HECK N C. Thermodynamics of sulfur poisoning in solid oxide fuel cells revisited:The effect of H2S concentration,temperature, current density and fuel utilization[J]. J Power Sources,2015, 296(20):92–101.
[33] SOHAL M S, OBRIEN J E, STOOTS C M, et al. Degradation issues in solid oxide cells during high temperature electrolysis[J]. J Fuel Cell Sci Technol, 2012, 9(1):1–10.
[34] MO?OTEGUY P, BRISSE A. A review and comprehensive analysis of degradation mechanisms of solid oxide electrolysis cells[J]. Int J Hydrogen Energ, 2013, 38(36):15887–15902.
[35] HAUCH A, EBBESEN S D, JENSEN S H, et al. Solid oxide electrolysis cells:Microstructure and degradation of the Ni/Yttria-stabilized zirconia electrode[J]. J Electrochem Soc, 2008,155(11):B1184–B1193.
[36] COSTA-NUNES O, GORTE R J, VOHS J M. Comparison of the performance of Cu–CeO2–YSZ and Ni–YSZ composite SOFC anodes with H2, CO, and syngas[J]. J Power Sources, 2005, 141(2):241–249.
[37] CAROLLO G, GARBUJO A, BEDON A, et al. Cu/CGO cermet based electrodes for symmetric and reversible solid oxide fuel cells[J]. Int J Hydrogen Energ, 2020, 45(25):13652–13658.
[38] LIU L, WANG Y, ZHOU X, et al. Cu/Ce0.6Mn0.3Fe0.1O2–δmembrane fuel electrode fabricated by infiltration method for solid oxide electrochemical cells[J]. Electrochim Acta, 2017, 235:365–373.
[39] GORTE R. Recent developments on anodes for direct fuel utilization in SOFC[J]. Solid State Ionics, 2004, 175(1–4):1–6.
[40] CIMENTI M, HILL J M. Direct utilization of ethanol on ceria-based anodes for solid oxide fuel cells[J]. Asia-Pac J Chem Eng, 2009, 4(1):45–54.
[41] GAMBLE S. Fabrication–microstructure–performance relationships of reversible solid oxide fuel cell electrodes—Review[J]. Mater Sci Technol, 2013, 27(10):1485–1497.
[42] MOGENSEN M B. Materials for reversible solid oxide cells[J]. Curr Opin Electrochem, 2020, 21:265–273.
[43] MOGENSEN M B, CHEN M, FRANDSEN H L, et al. Reversible solid-oxide cells for clean and sustainable energy[J]. Clean Energ,2019, 3(3):175–201.
[44] CHEN Y, BUNCH J, LI T, et al. Novel functionally graded acicular electrode for solid oxide cells fabricated by the freeze-tape-casting process[J]. J Power Sources, 2012, 213:93–99.
[45]陈龙.固体氧化物电池的相转化制备和性能表征[D].安徽:中国科学技术大学, 2015.CHEN Long. Phase-inversion fabrcation and characterization of solid oxide cells(in Chinese, dissertation). Anhui:University of Science and Technology of China, 2015.
[46] MAHATO N, BANERJEE A, GUPTA A, et al. Progress in material selection for solid oxide fuel cell technology:A review[J]. Prog Mater Sci, 2015, 72:141–337.
[47] ZHENG Y, WANG J, YU B, et al. A review of high temperature co-electrolysis of H2O and CO2 to produce sustainable fuels using solid oxide electrolysis cells(SOECs):Advanced materials and technology[J]. Chem Soc Rev, 2017, 46(5):1427–1463.
[48] HOSOI K, HAGIWARA H, IDA S, et al. La0.8Sr0.2FeO3-δas fuel electrode for solid oxide reversible cells using lagao3-based oxide electrolyte[J]. J Phys Chem C, 2016, 120(29):16110–16117.
[49] XU J, ZHOU X, PAN L, et al. Oxide composite of La0.3Sr0.7Ti0.3Fe0.7O3-δand CeO2 as an active fuel electrode for reversible solid oxide cells[J]. J Power Sources, 2017, 371:1–9.
[50] LING Y, CHEN L, LIN B, et al. Synthesis and characterization of a Sr0.95Y0.05TiO3-δ-based hydrogen electrode for reversible solid oxide cells[J]. RSC Adv, 2015, 5(22):17000–17006.
[51] RUAN C, XIE K, YANG L, et al. Efficient carbon dioxide electrolysis in a symmetric solid oxide electrolyzer based on nanocatalyst-loaded chromate electrodes[J]. Int J Hydrogen Energ, 2014, 39(20):10338–10348.
[52] XU S, CHEN S, LI M, et al. Composite cathode based on Fe-loaded LSCM for steam electrolysis in an oxide-ion-conducting solid oxide electrolyser[J]. J Power Sources, 2013, 239:332–340.
[53] GAN Y, QIN Q, CHEN S, et al. Composite cathode La0.4Sr0.4TiO3-δ–Ce0.8Sm0.2O2-δimpregnated with Ni for high-temperature steam electrolysis[J]. J Power Sources, 2014, 245:245–255.
[54] MADSEN B D, KOBSIRIPHAT W, WANG Y, et al. Nucleation of nanometer-scale electrocatalyst particles in solid oxide fuel cell anodes[J]. J Power Sources, 2007, 166(1):64–67.
[55] YANG C, YANG Z, JIN C, et al. High performance solid oxide electrolysis cells using Pr0.8Sr1.2(Co,Fe)0.8Nb0.2O4+δ-Co–Fe alloy hydrogen electrodes[J]. Int J Hydrogen Energ, 2013, 38(26):11202–11208.
[56] YANG C, YANG Z, JIN C, et al. Sulfur-tolerant redox-reversible anode material for direct hydrocarbon solid oxide fuel cells[J]. Adv Mater,2012, 24(11):1439–1443.
[57] YANG Z, MA C, WANG N, et al. Electrochemical reduction of CO2 in a symmetrical solid oxide electrolysis cell with La0.4Sr0.6Co0.2Fe0.7Nb0.1O3–δelectrode[J]. J CO2 Util, 2019, 33:445–451.
[58] YANG Z, CHEN Y, XU N, et al. Stability investigation for symmetric solid oxide fuel cell with La0.4Sr0.6Co0.2Fe0.7Nb0.1O3–δelectrode[J]. J Electrochem Soc, 2015, 162(7):F718–F721.
[59] ZHANG X, O'BRIEN J E, O’BRIEN R C, et al. Durability evaluation of reversible solid oxide cells[J]. J Power Sources, 2013, 242:566–574.
[60] JIANG S P. Development of lanthanum strontium manganite perovskite cathode materials of solid oxide fuel cells:A review[J]. J Mater Sci, 2008, 43(21):6799–6833.
[61] YANG C, COFFIN A, CHEN F. High temperature solid oxide electrolysis cell employing porous structured(La0.75Sr0.25)0.95MnO3with enhanced oxygen electrode performance[J]. Int J Hydrogen Energ,2010, 35(8):3221–3226.
[62] KIM J, JI H I, DASARI H P, et al. Degradation mechanism of electrolyte and air electrode in solid oxide electrolysis cells operating at high polarization[J]. Int J Hydrogen Energ, 2013, 38(3):1225–1235.
[63] VIRKAR A V. Mechanism of oxygen electrode delamination in solid oxide electrolyzer cells[J]. Int J Hydrogen Energ, 2010, 35(18):9527–9543.
[64] JUNG G B, CHANG C T, YEH C C, et al. Study of reversible solid oxide fuel cell with different oxygen electrode materials[J]. Int J Hydrogen Energ, 2016, 41(46):21802–21811.
[65] CHEN K, AI N, JIANG S P. Performance and structural stability of Gd0.2Ce0.8O1.9 infiltrated La0.8Sr0.2MnO3 nano-structured oxygen electrodes of solid oxide electrolysis cells[J]. Int J Hydrogen Energ,2014, 39(20):10349–10358.
[66] PETROV A N, KONONCHUK O F, ANDREEV A V, et al. Crystal structure, electrical and magnetic properties of La1–x Srx CoO3–y[J]. Solid State Ionics, 1995, 80(3–4):189–199.
[67] WANG W, HUANG Y, JUNG S, et al. A comparison of LSM, LSF, and LSCo for solid oxide electrolyzer anodes[J]. J Electrochem Soc, 2006,153(11):A2066–A2070.
[68] SHARMA V I, YILDIZ B. Degradation mechanism in La0.8Sr0.2Co O3as contact layer on the solid oxide electrolysis cell anode[J]. J Electrochem Soc, 2010, 157(3):B441–B448.
[69] ZHAO F, PENG R, XIA C. A La0.6Sr0.4CoO3-δ-based electrode with high durability for intermediate temperature solid oxide fuel cells[J].Mater Res Bull, 2008, 43(2):370–376.
[70] HIDEKO HAYASHI, MARIKO KANOH, CHANG JI QUAN, et al.Thermal expansion of Gd-doped ceria and reduced ceria[J]. Solid State Ionics, 2000, 132(3/4.):227–233.
[71] ZHENG Y, LI Q, CHEN T, et al. Comparison of performance and degradation of large-scale solid oxide electrolysis cells in stack with different composite air electrodes[J]. Int J Hydrogen Energ, 2015,40(6):2460–2472.
[72] TIETZ F, SEBOLD D, BRISSE A, et al. Degradation phenomena in a solid oxide electrolysis cell after 9000 h of operation[J]. J Power Sources, 2013, 223:129–135.
[73] LAGUNA-BERCERO M A, KILNER J A, SKINNER S J.Development of oxygen electrodes for reversible solid oxide fuel cells with scandia stabilized zirconia electrolytes[J]. Solid State Ionics, 2011,192(1):501–504.
[74] FAN H, KEANE M, LI N, et al. Electrochemical stability of La0.6Sr0.4Co0.2Fe0.8O3-δ-infiltrated YSZ oxygen electrode for reversible solid oxide fuel cells[J]. Int J Hydrogen Energ, 2014, 39(26):14071–14078.
[75] UCHIDA H, NISHINO H, KAKINUMA K, et al. Further improvement of performances and durability of oxygen and hydrogen electrodes for reversible solid oxide cells[J]. ECS Trans, 2019, 91(1):2379–2386.
[76] ZHOU N, YIN Y M, LI J, et al. A robust high performance cobalt-free oxygen electrode La0.5Sr0.5Fe0.8Cu0.15Nb0.05O3–δfor reversible solid oxide electrochemical cell[J]. J Power Sources, 2017, 340:373–379.
[77] CHRZAN A, OVTAR S, JASINSKI P, et al. High performance LaNi1-x Cox O3–δ(x=0.4 to 0.7)infiltrated oxygen electrodes for reversible solid oxide cells[J]. J Power Sources, 2017, 353:67–76.
[78] TAN Y, WANG A, JIA L, et al. High-performance oxygen electrode for reversible solid oxide cells with power generation and hydrogen production at intermediate temperature[J]. Int J Hydrogen Energ, 2017,42(7):4456–4464.
[79] NI C, IRVINE J T. Calcium manganite as oxygen electrode materials for reversible solid oxide fuel cell[J]. Faraday Discuss, 2015, 182:289–305.
[80] MENG X, SHEN Y, XIE M, et al. Novel solid oxide cells with SrCo0.8Fe0.1Ga0.1O3-δoxygen electrode for flexible power generation and hydrogen production[J]. J Power Sources, 2016, 306:226–232.
[81] CHAUVEAU F, MOUGIN J, BASSAT J M, et al. A new anode material for solid oxide electrolyser:The neodymium nickelate Nd2NiO4+δ[J]. J Power Sources, 2010, 195(3):744–749.
[82] CHAUVEAU F, MOUGIN J, MAUVY F, et al. Development and operation of alternative oxygen electrode materials for hydrogen production by high temperature steam electrolysis[J]. Int J Hydrogen Energ, 2011, 36(13):7785–7790.
[83] LAGUNA-BERCERO M A, MONZóN H, LARREA A, et al.Improved stability of reversible solid oxide cells with a nickelate-based oxygen electrode[J]. J Mater Chem A, 2016, 4(4):1446–1453.
[84] MONTENEGRO-HERNáNDEZ A, VEGA-CASTILLO J, MOGNI L,et al. Thermal stability of Ln2NiO4+δ(Ln:La, Pr, Nd)and their chemical compatibility with YSZ and CGO solid electrolytes[J]. Int J Hydrogen Energ, 2011, 36(24):15704–15714.
[85] BASTIDAS D M, TAO S, IRVINE J T S. A symmetrical solid oxide fuel cell demonstrating redox stable perovskite electrodes[J]. J Mater Chem, 2006, 16(17):1603–1605.
[86] LUO X, YANG Y, YANG Y, et al. Reduced-temperature redox-stable LSM as a novel symmetrical electrode material for SOFCs[J].Electrochim Acta, 2018, 260:121–128.
[87] RUIZ-MORALES J C, MARRERO-LóPEZ D, CANALES-VáZQUEZ J, et al. Symmetric and reversible solid oxide fuel cells[J]. Rsc Adv,2011, 1(8):1403.
[88] CAO Z, ZHANG Y, MIAO J, 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(46):16572–16577.
[89] CAO Z, WEI B, MIAO J, et al. Efficient electrolysis of CO2 in symmetrical solid oxide electrolysis cell with highly active La0.3Sr0.7Fe0.7Ti0.3O3 electrode material[J]. Electrochem Commun,2016, 69:80–83.
[90] ADDO P K, MOLERO-SANCHEZ B, CHEN M, et al. CO/CO2 study of high performance La0.3Sr0.7Fe0.7Cr0.3O3–δreversible SOFC electrodes[J]. Fuel Cells, 2015, 15(5):689–696.
[91] BIAN L, DUAN C, WANG L, et al. Highly efficient, redox-stable,La0.5Sr0.5Fe0.9Nb0.1O3–δsymmetric electrode for both solid-oxide fuel cell and H2O/CO2 Co-electrolysis operation[J]. J Electrochem Soc,2018, 165(11):F981–F985.
[92] PENG X, TIAN Y, LIU Y, et al. An efficient symmetrical solid oxide electrolysis cell with LSFM-based electrodes for direct electrolysis of pure CO2[J]. J CO2 Util, 2020, 36:18–24.
[93] LIU L, SUN K, LI X, et al. A novel doped CeO2–LaFeO3 composite oxide as both anode and cathode for solid oxide fuel cells[J]. Int J Hydrogen Energ, 2012, 37(17):12574–12579.
[94] TASKIN A A, LAVROV A N, ANDO Y. Achieving fast oxygen diffusion in perovskites by cation ordering[J]. Appl Phys Lett, 2005,86(9):091910.
[95] LIU Q, DONG X, XIAO G, et al. A novel electrode material for symmetrical SOFCs[J]. Adv Mater, 2010, 22(48):5478–5482.
[96] LIU Q, YANG C, DONG X, et al. Perovskite Sr2Fe1.5Mo0.5O6-δas electrode materials for symmetrical solid oxide electrolysis cells[J]. Int J Hydrogen Energ, 2010, 35(19):10039–10044.
[97] GUO Y, GUO T, ZHOU S, et al. Characterization of Sr2Fe1.5Mo0.5O6–δ-Gd0.1Ce0.9O1.95 symmetrical electrode for reversible solid oxide cells[J]. Ceram Int, 2019, 45(8):10969–10975.
[98] XU J, ZHOU X, CHENG J, et al. Electrochemical performance of highly active ceramic symmetrical electrode La0.3Sr0.7Ti0.3Fe0.7O3–δ-CeO2 for reversible solid oxide cells[J].Electrochim Acta, 2017, 257:64–72.
[99] LI Y, ZOU S, JU J, et al. Characteristics of nano-structured SFM infiltrated onto YSZ backbone for symmetrical and reversible solid oxide cells[J]. Solid State Ionics, 2018, 319:98–104.
[100] SU C, WANG W, LIU M, et al. Progress and prospects in symmetrical solid oxide fuel cells with two identical electrodes[J]. Adv Energ Mater, 2015, 5(14):1–19.
[101] ADIJANTO L, BALAJI PADMANABHAN V, KüNGAS R, et al.Transition metal-doped rare earth vanadates:a regenerable catalytic material for SOFC anodes[J]. J Mater Chem, 2012, 22(22):11396–11402.
[102] ZHOU J, WANG N, CUI J, et al. Structural and electrochemical properties of B-site Ru-doped(La0.8Sr0.2)0.9Sc0.2Mn0.8O3–δas symmetrical electrodes for reversible solid oxide cells[J]. J Alloys Compd, 2019, 792:1132–1140.
[103] AKIKUR R K, SAIDUR R, PING H W, et al. Performance analysis of a co-generation system using solar energy and SOFC technology[J].Energ Convers Manage, 2014, 79:415–430.
[104] GIAP V T, LEE Y D, KIM Y S, et al. A novel electrical energy storage system based on a reversible solid oxide fuel cell coupled with metal hydrides and waste steam[J]. Appl Energ, 2020, 262.
[105] LUO Y, SHI Y, ZHENG Y, et al. Reversible solid oxide fuel cell for natural gas/renewable hybrid power generation systems[J]. J Power Sources, 2017, 340:60–70.
[106] REN J, GAMBLE S R, ROSCOE A J, et al. Modeling a reversible solid oxide fuel cell as a storage device within AC power networks[J].Fuel Cells, 2012, 12(5):773–786.
[107] SONG P, ZHOU Y, ZHANG Y, et al. The study on the role of reversible solid oxide cell(rsoc)in sector-coupling of energy systems[C]//International Conference on Power System Technology,Guangzhou, China, 2018:6–8.
[108] VILLARREAL SINGER D. Reversible solid oxide cells for bidirectional energy conversion in spot electricity and fuel markets(in dissertation). New York, United state:Columbia University, 2017.
[109] WENDEL C H, KAZEMPOOR P, BRAUN R J. Novel electrical energy storage system based on reversible solid oxide cells:System design and operating conditions[J]. J Power Sources, 2015, 276:133–144.
[110] MINH N Q. Development of reversible solid oxide fuel cells(RSOFCs)and stacks[J]. ECS Trans, 2011, 35:2897–2904.
[111] NGUYEN V N, FANG Q, PACKBIER U, et al. Long-term tests of a Jülich planar short stack with reversible solid oxide cells in both fuel cell and electrolysis modes[J]. Int J Hydrogen Energ, 2013, 38(11):4281–4290.
[112] CHEN B, HAJIMOLANA Y S, VENKATARAMAN V, et al.Integration of reversible solid oxide cells with methane synthesis(ReSOC-MS)in grid stabilization:A dynamic investigation[J]. Appl Energ, 2019, 250:558–567.
基本信息:
DOI:10.14062/j.issn.0454-5648.20200434
中图分类号:TB34;TM911.4
引用信息:
[1]杨志宾,张盼盼,雷泽,等.可逆固体氧化物电池电极材料研究进展[J].硅酸盐学报,2021,49(01):56-69.DOI:10.14062/j.issn.0454-5648.20200434.
基金信息:
国家重点研发计划(2018YFE0106700); 国家自然基金(52072405); 国家电网科技项目(5419-201999355A-0-0-00)
2020-06-18
2020
2020-12-04
2020-10-22
2020
1
2020-12-17
2020-12-17
2020-12-17