Technological limitations and recent developments in a solid oxide electrolyzer cell: A review

[1]  Xinfa Chen,et al.  Ni-based heterostructure with protective phosphide layer to enhance the oxygen evolution reaction for the seawater electrolysis , 2023, International Journal of Hydrogen Energy.

[2]  L. Zou,et al.  Brief review of hydrocarbon-reforming catalysts map for hydrogen production , 2023, Energy Reviews.

[3]  Yu Qin,et al.  Operation optimisation of integrated energy systems based on cooperative game with hydrogen energy storage systems , 2023, International Journal of Hydrogen Energy.

[4]  Shao-Long Wang,et al.  Fabrication of Anode Supported Solid Oxide Electrolysis Cell with the Co-Tape Casting Technique and Study on Co-Electrolysis Characteristics , 2023, SSRN Electronic Journal.

[5]  M. Alghoul,et al.  Hydrogen fuel as an important element of the energy storage needs for future smart cities , 2023, International Journal of Hydrogen Energy.

[6]  Yixin Liu,et al.  Correlation between the thickness of NiFe2O4 and hydrogen production performance for solid oxide electrolysis cells , 2023, International Journal of Hydrogen Energy.

[7]  Zhibin Yang,et al.  Cobalt-free perovskite Ba0.95La0.05FeO3-δ as efficient and durable oxygen electrode for solid oxide electrolysis cells , 2023, International Journal of Hydrogen Energy.

[8]  Aditi Pandey,et al.  Generation of green hydrogen using self-sustained regenerative fuel cells: Opportunities and challenges , 2023, International Journal of Hydrogen Energy.

[9]  S. Emery,et al.  Skilling the green hydrogen economy: A case study from Australia , 2023, International Journal of Hydrogen Energy.

[10]  Jianxin Lin,et al.  Optimal planning for industrial park-integrated energy system with hydrogen energy industry chain , 2023, International journal of hydrogen energy.

[11]  Yuanzheng Li,et al.  Control-oriented dynamic process optimization of solid oxide electrolysis cell system with the gas characteristic regarding oxygen electrode delamination , 2023, Applied Energy.

[12]  O. Guillon,et al.  Electro-chemo-mechanical analysis of a solid oxide cell based on doped ceria , 2022, Journal of Power Sources.

[13]  J. Otomo,et al.  Design and Evaluation of Hydrogen Energy Storage Systems Using Metal Oxides , 2022, Energy & Fuels.

[14]  H. Park,et al.  Environ-economic analysis of high-temperature steam electrolysis for decentralized hydrogen production , 2022, Energy Conversion and Management.

[15]  G. Volkova,et al.  Effects of YSZ ceramics doping with silica and alumina on its structure and properties , 2022, Materials Chemistry and Physics.

[16]  W. Shuai,et al.  Dynamic behavior of high-temperature CO2/H2O co-electrolysis coupled with real fluctuating renewable power , 2022, Sustainable Energy Technologies and Assessments.

[17]  F. Ciucci,et al.  Nano film Pr2Ni0.8Cu0.2O4+δ decorated La0.6Sr0.4Co0.2Fe0.8O3-δ oxygen electrode for highly efficient and stable reversible solid oxide cells , 2022, Electrochimica Acta.

[18]  Mingjue Zhou,et al.  Three-Dimensional Modeling and Performance Study of High Temperature Solid Oxide Electrolysis Cell with Metal Foam , 2022, Sustainability.

[19]  Jiang Liu,et al.  Solid oxide cells with cermet of silver and gadolinium-doped-ceria symmetrical electrodes for high-performance power generation and water electrolysis , 2022, International Journal of Hydrogen Energy.

[20]  Dong-qi Zhao,et al.  Modeling and analysis of cross-flow solid oxide electrolysis cell with oxygen electrode/electrolyte interface oxygen pressure characteristics for hydrogen production , 2022, Journal of Power Sources.

[21]  Chung‐Jen Tseng,et al.  Review on the Preparation of Electrolyte Thin Films based on Cerate-Zirconate Oxides for Electrochemical Analysis of Anode-supported Proton Ceramic Fuel Cells , 2022, Journal of Alloys and Compounds.

[22]  N. Kumari,et al.  Electrochemical Modeling and Simulation of CO 2 Reduction in Solid Oxide Electrolysis Cells , 2022, Journal of Hazardous, Toxic, and Radioactive Waste.

[23]  P. Kazempoor,et al.  Validation challenges in solid oxide electrolysis cell modeling fueled by low Steam/CO2 ratio , 2022, International Journal of Hydrogen Energy.

[24]  B. Chi,et al.  Sr-free orthorhombic perovskite Pr0.8Ca0.2Fe0.8Co0.2O3-δ as a high-performance air electrode for reversible solid oxide cell , 2022, Journal of Power Sources.

[25]  M. Ni,et al.  Multi-objective optimizations of solid oxide co-electrolysis with intermittent renewable power supply via multi-physics simulation and deep learning strategy , 2022, Energy Conversion and Management.

[26]  B. Chi,et al.  Pd-La0.6Sr0.4Co0.2Fe0.8O3– composite as active and stable oxygen electrode for reversible solid oxide cells , 2022, Journal of Rare Earths.

[27]  S. Frangini,et al.  Protective Coatings for Ferritic Stainless Steel Interconnect Materials in High Temperature Solid Oxide Electrolyser Atmospheres , 2022, Energies.

[28]  Guntae Kim,et al.  Progress and potential for symmetrical solid oxide electrolysis cells , 2022, Matter.

[29]  M. Mogensen,et al.  Current understanding of ceria surfaces for CO2 reduction in SOECs and future prospects – A review , 2022, Solid State Ionics.

[30]  S. Singhal,et al.  Electrochemical performance and durability of flat-tube solid oxide electrolysis cells for H2O/CO2 co-electrolysis , 2022, International Journal of Hydrogen Energy.

[31]  Zhibin Yang,et al.  A study on solid oxide electrolyzer stack and system performance based on alternative mapping models , 2022, International Journal of Hydrogen Energy.

[32]  Fang Wang,et al.  Modeling and evaluation of sintered microstructure and its properties for rSOFC fuel electrodes by coarse-grained molecular dynamics , 2022, Journal of Alloys and Compounds.

[33]  J. Qi,et al.  Joining 3YSZ Electrolyte to AISI 441 Interconnect Using the Ag Particle Interlayer: Enhanced Mechanical and Aging Properties , 2021, Crystals.

[34]  In-Beum Lee,et al.  An integrative process of blast furnace and SOEC for hydrogen utilization: Techno-economic and environmental impact assessment , 2021, Energy Conversion and Management.

[35]  M. Ni,et al.  Ni migration of Ni-YSZ electrode in solid oxide electrolysis cell: An integrated model study , 2021, Journal of Power Sources.

[36]  Jongsup Hong,et al.  Sensitivity analysis of a solid oxide co-electrolysis cell system with respect to its key operating parameters and optimization with its performance map , 2021, Energy Conversion and Management.

[37]  Xinxin Wang,et al.  Comprehensive understanding of alkaline-earth elements effects on electrocatalytic activity and stability of LaFe0.8Ni0.2O3 electrode for high-temperature CO2 electrolysis , 2021, Journal of CO2 Utilization.

[38]  B. Tu,et al.  Extreme management strategy and thermodynamic analysis of high temperature H2O/CO2 co-electrolysis for energy conversion , 2021, Renewable Energy.

[39]  S. Singhal,et al.  Performance of CO2 electrolysis using solid oxide electrolysis cell with Ni-YSZ as fuel electrode under different fuel atmospheres , 2021, International Journal of Green Energy.

[40]  J. Tong,et al.  Stable perovskite-fluorite dual-phase composites synthesized by one-pot solid-state reactive sintering for protonic ceramic fuel cells , 2021, Ceramics International.

[41]  J. Brouwer,et al.  Dynamics and control of a thermally self-sustaining energy storage system using integrated solid oxide cells for an islanded building , 2021, International Journal of Hydrogen Energy.

[42]  Huanting Wang,et al.  Recent development of perovskite oxide-based electrocatalysts and their applications in low to intermediate temperature electrochemical devices , 2021, Materials Today.

[43]  Lijun Wang,et al.  Excellent Electrochemical Performance of La0.3Sr0.7Fe0.9Ti0.1O3-δ as a Symmetric Electrode for Solid Oxide Cells. , 2021, ACS applied materials & interfaces.

[44]  S. Björklund,et al.  Tribological performance assessment of Al2O3-YSZ composite coatings deposited by hybrid powder-suspension plasma spraying , 2021, Surface and Coatings Technology.

[45]  O. Guillon,et al.  Performance Benchmark of Planar Solid Oxide Cells Based on Material Development and Designs , 2021 .

[46]  Haoran Xu,et al.  Advancing the multiscale understanding on solid oxide electrolysis cells via modelling approaches: A review , 2021 .

[47]  Jinliang Yuan,et al.  Performance analysis of mesoscale reactions in fuel electrode and effect on dynamic multiphysics processes in rSOFC with syngas , 2021 .

[48]  Lan Xia,et al.  Design and optimization of hydrogen production by solid oxide electrolyzer with marine engine waste heat recovery and ORC cycle , 2021 .

[49]  Xiao-dong Wang,et al.  Thermodynamic study of a hybrid PEMFC-solar energy multi-generation system combined with SOEC and dual Rankine cycle , 2020 .

[50]  Yan Cao,et al.  A solar-driven lumped SOFC/SOEC system for electricity and hydrogen production: 3E analyses and a comparison of different multi-objective optimization algorithms , 2020 .

[51]  Xingbo Liu,et al.  Degradation of solid oxide electrolysis cells: Phenomena, mechanisms, and emerging mitigation strategies—A review , 2020 .

[52]  M. Lang,et al.  Long‐Term Behavior of a Solid Oxide Electrolyzer (SOEC) Stack ▴ , 2020, Fuel Cells.

[53]  I. Danilenko,et al.  Effect of alumina added by mechanical mixing and co-doping on the densification mechanisms of zirconia nanoparticles at the initial stage of sintering , 2020 .

[54]  A. Khouya Levelized costs of energy and hydrogen of wind farms and concentrated photovoltaic thermal systems. A case study in Morocco , 2020 .

[55]  F. Chen,et al.  Energy storage and hydrogen production by proton conducting solid oxide electrolysis cells with a novel heterogeneous design , 2020 .

[56]  N. Menzler,et al.  Performance assessment of industrial-sized solid oxide cells operated in a reversible mode: Detailed numerical and experimental study , 2020 .

[57]  K. Rezwan,et al.  Tailoring electrostatic surface potential and adsorption capacity of porous ceramics by silica-assisted sintering , 2020 .

[58]  U. Ozkan,et al.  Temperature-induced changes in the synthesis gas composition in a high-temperature H2O and CO2 co-electrolysis system , 2020 .

[59]  M. Ni,et al.  Three‐dimensional Modeling and Performance Optimization of Proton Conducting Solid Oxide Electrolysis Cell ▴ , 2020, Fuel Cells.

[60]  Yonghua Song,et al.  Time-Varying Model Predictive Control of a Reversible-SOC Energy-Storage Plant Based on the Linear Parameter-Varying Method , 2020, IEEE Transactions on Sustainable Energy.

[61]  S. Frangini,et al.  Perovskite Conversion Coatings as Novel and Simple Approach for Improving Functional Performance of Ferritic Stainless Steel SOFC Interconnects , 2020, Fuel Cells.

[62]  M. Ni,et al.  Three-dimensional modeling of flow field optimization for co-electrolysis solid oxide electrolysis cell , 2020 .

[63]  Yongping Yang,et al.  Reversible solid-oxide cell stack based power-to-x-to-power systems: Comparison of thermodynamic performance , 2020, Applied Energy.

[64]  A. Tarancón,et al.  High-performing electrolyte-supported symmetrical solid oxide electrolysis cells operating under steam electrolysis and co-electrolysis modes , 2020 .

[65]  J. Qi,et al.  Oxidation behavior of ferritic stainless steel interconnect coated by a simple diffusion bonded cobalt protective layer for solid oxide fuel cells , 2020, Corrosion Science.

[66]  T. Sornchamni,et al.  Comparison of ceria and zirconia based electrolytes for solid oxide electrolysis cells , 2020 .

[67]  A. Lanzini,et al.  Energy performance of Power-to-Liquid applications integrating biogas upgrading, reverse water gas shift, solid oxide electrolysis and Fischer-Tropsch technologies , 2020, Energy Conversion and Management: X.

[68]  Ming Liu,et al.  Dynamic modeling and parameter analysis study on reversible solid oxide cells during mode switching transient processes , 2020, Applied Energy.

[69]  Jack Brouwer,et al.  Dynamic dispatch of solid oxide electrolysis system for high renewable energy penetration in a microgrid , 2020 .

[70]  S. Haile,et al.  A review of defect structure and chemistry in ceria and its solid solutions. , 2019, Chemical Society reviews.

[71]  C. Hochenauer,et al.  Performance of a ten-layer reversible Solid Oxide Cell stack (rSOC) under transient operation for autonomous application , 2019, Applied Energy.

[72]  Chung‐Jen Tseng,et al.  Effects of TiO2 and SDC addition on the properties of YSZ electrolyte , 2019, International Journal of Hydrogen Energy.

[73]  S. Chan,et al.  Study of CO2 and H2O direct co-electrolysis in an electrolyte-supported solid oxide electrolysis cell by aqueous tape casting technique , 2019, International Journal of Hydrogen Energy.

[74]  U. Ozkan,et al.  Hydrogen Production from Water in a Solid Oxide Electrolysis Cell: Effect of Ni Doping on Lanthanum Strontium Ferrite Perovskite Cathodes , 2019, Industrial & Engineering Chemistry Research.

[75]  Limei Yan,et al.  Modelling the performance of an SOEC by optimization of neural network with MPSO algorithm , 2019, International Journal of Hydrogen Energy.

[76]  A. Mahmood,et al.  Performance evaluation of SOEC for CO2/H2O co-electrolysis: Considering the effect of cathode thickness , 2019, Journal of CO2 Utilization.

[77]  S. Frangini,et al.  Effect of additive particle size on the CuO-accelerated formation of LaFeO3 perovskite conversion coatings in molten carbonate baths , 2019, Surface and Coatings Technology.

[78]  O. Deutschmann,et al.  Performance analysis of a reversible solid oxide cell system based on multi-scale hierarchical solid oxide cell modelling , 2019, Energy Conversion and Management.

[79]  Ligang Wang,et al.  Power-to-methane via co-electrolysis of H2O and CO2: The effects of pressurized operation and internal methanation , 2019, Applied Energy.

[80]  Henrik Lund Frandsen,et al.  A fully-homogenized multiphysics model for a reversible solid oxide cell stack , 2019, International Journal of Hydrogen Energy.

[81]  Xiongwen Zhang,et al.  Numerical investigations for a solid oxide electrolyte cell stack , 2019, International Journal of Hydrogen Energy.

[82]  S. Gupta,et al.  Defect evolution in Eu3+, Nb5+ doped and co-doped CeO2: X-ray diffraction, positron annihilation lifetime and photoluminescence studies , 2019, Inorganic Chemistry Frontiers.

[83]  Xiuli Hu,et al.  Active and stable Ni/Cr2O3-δ cathodes for high temperature CO2 electrolysis , 2019, Journal of Power Sources.

[84]  N. Simonenko,et al.  Synthesis of BaCe0.9xZrxY0.1O3 nanopowders and the study of proton conductors fabricated on their basis by low-temperature spark plasma sintering , 2019, International Journal of Hydrogen Energy.

[85]  O. Posdziech,et al.  Efficient hydrogen production for industry and electricity storage via high-temperature electrolysis , 2019, International Journal of Hydrogen Energy.

[86]  M. Ni,et al.  Progress Report on Proton Conducting Solid Oxide Electrolysis Cells , 2019, Advanced Functional Materials.

[87]  A. Mai,et al.  Chromium Oxidation and Evaporation on Interconnects from a Stack and CHP-Systems Perspective , 2019, ECS Transactions.

[88]  A. Nakajo,et al.  Effects of Polarization on the Microstructural Changes at the YSZ/Ni-YSZ Interface , 2019, ECS Transactions.

[89]  O. Himanen,et al.  Method to Measure Area Specific Resistance and Chromium Migration Simultaneously from Solid Oxide Fuel Cell Interconnect Materials , 2019, Fuel Cells.

[90]  R. Ihringer,et al.  Electrical Conductivity Behaviour of Ferritic Steel Interconnect in Function of Spinel Composition, Electrode Material and Thermal Cycles , 2019, ECS Transactions.

[91]  P. G. Moses,et al.  Progress in SOEC Development Activities at Haldor Topsøe , 2019, ECS Transactions.

[92]  U. Ozkan,et al.  Production of syngas with controllable H2/CO ratio by high temperature co-electrolysis of CO2 and H2O over Ni and Co- doped lanthanum strontium ferrite perovskite cathodes , 2019, Applied Catalysis B: Environmental.

[93]  M. Petitjean,et al.  Transition Cycles during Operation of a Reversible Solid Oxide Electrolyzer/Fuel Cell (rSOC) System , 2019, Fuel Cells.

[94]  M. Rokni,et al.  Enhancement of energy generation efficiency in industrial facilities by SOFC – SOEC systems with additional hydrogen production , 2019, International Journal of Hydrogen Energy.

[95]  J. Bentzen,et al.  Boosting the performance and durability of Ni/YSZ cathode for hydrogen production at high current densities via decoration with nano-sized electrocatalysts. , 2019, Nanoscale.

[96]  M. Mehrpooya,et al.  Thermodynamic and economic analyses of hydrogen production system using high temperature solid oxide electrolyzer integrated with parabolic trough collector , 2019, Journal of Cleaner Production.

[97]  Lixin Sun,et al.  Threshold catalytic onset of carbon formation on CeO2 during CO2 electrolysis: mechanism and inhibition , 2019, Journal of Materials Chemistry A.

[98]  B. Boukamp,et al.  Accelerated degradation of yttria stabilized zirconia electrolyte during high-temperature water electrolysis , 2019, Journal of Solid State Electrochemistry.

[99]  M. Salvo,et al.  Effect of electric load and dual atmosphere on the properties of an alkali containing diopside-based glass sealant for solid oxide cells , 2019, Journal of Power Sources.

[100]  Guobin Zhang,et al.  Modelling of effect of pressure on co-electrolysis of water and carbon dioxide in solid oxide electrolysis cell , 2019, International Journal of Hydrogen Energy.

[101]  S. Neophytides,et al.  Experimental Clarification of the RWGS Reaction Effect in H2O/CO2 SOEC Co-Electrolysis Conditions , 2019, Catalysts.

[102]  O. Deutschmann,et al.  Dynamic behavior and control strategy study of CO2/H2O co-electrolysis in solid oxide electrolysis cells , 2019, Journal of Power Sources.

[103]  A. Jakobsen,et al.  In-operando observation of microstructural evolution in a solid oxide cell electrolyte operating at high polarization , 2019, Journal of Power Sources.

[104]  H. Frandsen,et al.  Modeling the Mechanical Integrity of Generic Solid Oxide Cell Stack Designs Exposed to Long‐term Operation , 2018, Fuel Cells.

[105]  K. Friedrich,et al.  Transient reversible solid oxide cell reactor operation – Experimentally validated modeling and analysis , 2018, Applied Energy.

[106]  Junfa Zhu,et al.  Perovskite Oxyfluoride Electrode Enabling Direct Electrolyzing Carbon Dioxide with Excellent Electrochemical Performances , 2018, Advanced Energy Materials.

[107]  S. Giddey,et al.  CO2 reduction in a solid oxide electrolysis cell with a ceramic composite cathode: Effect of load and thermal cycling , 2018, International Journal of Hydrogen Energy.

[108]  O. Deutschmann,et al.  Hierarchical modeling of solid oxide cells and stacks producing syngas via H2O/CO2 Co-electrolysis for industrial applications , 2018, Applied Energy.

[109]  B. Boukamp,et al.  Premature degradation study of a cathode-supported solid oxide electrolysis cell , 2018, Journal of Solid State Electrochemistry.

[110]  Ji-cai Feng,et al.  Joining of solid oxide fuel/electrolysis cells at low temperature: A novel method to obtain high strength seals already at 300 °C , 2018, Journal of Power Sources.

[111]  I. Dincer,et al.  Modeling and performance optimization of a solid oxide electrolysis system for hydrogen production , 2018, Applied Energy.

[112]  Hyoungchul Kim,et al.  A 5 × 5 cm2 protonic ceramic fuel cell with a power density of 1.3 W cm–2 at 600 °C , 2018, Nature Energy.

[113]  F. Smeacetto,et al.  A Ba‐free sealing glass with a high coefficient of thermal expansion and excellent interface stability optimized for SOFC/SOEC stack applications , 2018 .

[114]  B. Sundén,et al.  A three dimensional multiphysics model of a solid oxide electrochemical cell: A tool for understanding degradation , 2018, International Journal of Hydrogen Energy.

[115]  S. Jiang,et al.  Suppressed Sr segregation and performance of directly assembled La0.6Sr0.4Co0.2Fe0.8O3-δ oxygen electrode on Y2O3-ZrO2 electrolyte of solid oxide electrolysis cells , 2018 .

[116]  Đ. juričić,et al.  Modelling of anode delamination in solid oxide electrolysis cell and analysis of its effects on electrochemical performance , 2018 .

[117]  T. Bieler,et al.  Transient porous nickel interlayers for improved silver-based Solid Oxide Fuel Cell brazes , 2018 .

[118]  M. Ni,et al.  Activation and failure mechanism of La0.6Sr0.4Co0.2Fe0.8O3−δ air electrode in solid oxide electrolyzer cells under high-current electrolysis , 2018 .

[119]  D. Trimis,et al.  Power-to-Gas through High Temperature Electrolysis and Carbon Dioxide Methanation: Reactor Design and Process Modeling , 2018 .

[120]  Hongmei Yu,et al.  Water electrolysis based on renewable energy for hydrogen production , 2018 .

[121]  François Maréchal,et al.  Optimal design of solid-oxide electrolyzer based power-to-methane systems: A comprehensive comparison between steam electrolysis and co-electrolysis , 2018 .

[122]  Tak-Hyoung Lim,et al.  Hybrid-solid oxide electrolysis cell: A new strategy for efficient hydrogen production , 2018 .

[123]  Z. Jiao,et al.  Prediction of Nickel Morphological Evolution in Composite Solid Oxide Fuel Cell Anode Using Modified Phase Field Model , 2018 .

[124]  Seyoung Kim,et al.  Interfacial microstructure and shear strength of reactive air brazed oxygen transport membrane ceramic–metal alloy joints , 2018, Metals and Materials International.

[125]  K. Wiik,et al.  Comparison of iron and copper doped manganese cobalt spinel oxides as protective coatings for solid oxide fuel cell interconnects , 2017 .

[126]  Werner Lehnert,et al.  Performance and degradation of an SOEC stack with different cell components , 2017 .

[127]  Boxuan Yu,et al.  Electrochemical characterization and mechanism analysis of high temperature Co-electrolysis of CO2 and H2O in a solid oxide electrolysis cell , 2017 .

[128]  S. Chan,et al.  An evaluation of electrochemical performance of a solid oxide electrolyzer cell as a function of co-sintered YSZ-SDC bilayer electrolyte thickness , 2017 .

[129]  L. Barelli,et al.  Study of SOFC-SOE transition on a RSOFC stack , 2017 .

[130]  Zhengkai Tu,et al.  Modelling of solid oxide electrolyser cell using extreme learning machine , 2017 .

[131]  Jianqiang Wang,et al.  An insight into the effects of B-site transition metals on the activity, activation effect and stability of perovskite oxygen electrodes for solid oxide electrolysis cells , 2017 .

[132]  M. Pascual,et al.  Mechanical properties of solid oxide fuel cell glass-ceramic sealants in the system BaO/SrO-MgO-B2O3-SiO2 , 2017 .

[133]  I. Dincer,et al.  Thermodynamic and electrochemical analyses of a solid oxide electrolyzer for hydrogen production , 2017 .

[134]  Sea-Fue Wang,et al.  Characteristics of glass sealants for intermediate-temperature solid oxide fuel cell applications , 2017 .

[135]  Oliver Posdziech,et al.  Development and Demonstration of a Novel Reversible SOFC System for Utility and Micro Grid Energy Storage , 2017 .

[136]  S. Jensen,et al.  Investigation of a Spinel‐forming Cu‐Mn Foam as an Oxygen Electrode Contact Material in a Solid Oxide Cell Single Repeating Unit , 2017 .

[137]  X. Bao,et al.  Co-electrolysis of CO 2 and H 2 O in high-temperature solid oxide electrolysis cells: Recent advance in cathodes , 2017 .

[138]  S. Neophytides,et al.  Electrocatalytic performance and carbon tolerance of ternary Au-Mo-Ni/GDC SOFC anodes under CH4-rich Internal Steam Reforming conditions , 2017, Catalysis Today.

[139]  E. Siebert,et al.  Degradation mechanism of La0.6Sr0.4Co0.2Fe0.8O3-δ/Gd0.1Ce0.9O2-δ composite electrode operated under solid oxide electrolysis and fuel cell conditions , 2017 .

[140]  K. Wiik,et al.  Effect of coating density on oxidation resistance and Cr vaporization from solid oxide fuel cell interconnects , 2017 .

[141]  P. Hendriksen,et al.  A Novel SOFC/SOEC Sealing Glass with a Low SiO2 Content and a High Thermal Expansion Coefficient , 2017 .

[142]  S. Singhal,et al.  Advances in Solid Oxide Fuel Cells: Review of Progress through Three Decades of the International Symposia on Solid Oxide Fuel Cells , 2017 .

[143]  M. Mori,et al.  Measurement and Numerical Simulation of Temperature Distributions of a Micro-Tubular SOEC during H2O/CO2 Co-Electrolysis , 2017 .

[144]  S. Neophytides,et al.  Modified NiO/GDC Cermets as Possible Cathode Electrocatalysts for H 2 O Electrolysis and H 2 O/CO 2 Co-Electrolysis Processes in SOECs , 2017 .

[145]  Ludger Blum,et al.  SOC Development at Forschungszentrum Jülich , 2017 .

[146]  A. Brisse,et al.  23,000 h steam electrolysis with an electrolyte supported solid oxide cell , 2017 .

[147]  Z. Lü,et al.  High activity oxide Pr0.3Sr0.7Ti0.3Fe0.7O3−δ as cathode of SOEC for direct high-temperature steam electrolysis , 2017 .

[148]  Xiongwen Zhang,et al.  Comparative performance investigation of different gas flow configurations for a planar solid oxide electrolyzer cell , 2017 .

[149]  Ji-cai Feng,et al.  Reactive air brazing of YSZ-electrolyte and Al2O3-substrate for gas sensor sealing: Interfacial microstructure and mechanical properties , 2017 .

[150]  J. Svensson,et al.  Co- and Ce/Co-coated ferritic stainless steel as interconnect material for Intermediate Temperature Solid Oxide Fuel Cells , 2017 .

[151]  T. Shin,et al.  Fabrication and characterization of oxide ion conducting films, Zr1−xMxO2−δ (M = Y, Sc) on porous SOFC anodes, prepared by electron beam physical vapor deposition , 2017 .

[152]  G. Lasko,et al.  The Peculiarities of Structure Formation and Properties of Zirconia-Based Nanocomposites with Addition of Al2O3 and NiO , 2017, Nanoscale Research Letters.

[153]  Stig Wedel,et al.  Optimization of a new flow design for solid oxide cells using computational fluid dynamics modelling , 2016 .

[154]  Ludger Blum,et al.  Electrochemical characterization of Fe-air rechargeable oxide battery in planar solid oxide cell stacks , 2016 .

[155]  M. Ma̧czka,et al.  Effect of titania doping and sintering temperature on titanium local environment and electrical conductivity of YSZ , 2016 .

[156]  J. Pharoah,et al.  Comprehensive computational fluid dynamics model of solid oxide fuel cell stacks , 2016 .

[157]  L. Barelli,et al.  Solid oxide fuel cell modelling: Electrochemical performance and thermal management during load-following operation , 2016 .

[158]  M. Mogensen,et al.  Ni/YSZ electrodes structures optimized for increased electrolysis performance and durability , 2016 .

[159]  S. Ebbesen,et al.  Degradation of solid oxide cells during co-electrolysis of steam and carbon dioxide at high current densities , 2016 .

[160]  Guntae Kim,et al.  Achieving High Efficiency and Eliminating Degradation in Solid Oxide Electrochemical Cells Using High Oxygen-Capacity Perovskite. , 2016, Angewandte Chemie.

[161]  B. Sundén,et al.  Localized carbon deposition in solid oxide electrolysis cells studied by multiphysics modeling , 2016, Journal of Power Sources.

[162]  D. Hotza,et al.  Current developments in reversible solid oxide fuel cells , 2016 .

[163]  G. Taillades,et al.  High performance anode-supported proton ceramic fuel cell elaborated by wet powder spraying , 2016 .

[164]  Nikdalila Radenahmad,et al.  High conductivity and high density proton conducting Ba1−xSrxCe0.5Zr0.35Y0.1Sm0.05O3−δ (x = 0.5, 0.7, 0.9, 1.0) perovskites for IT-SOFC , 2016 .

[165]  Meilin Liu,et al.  Effects of doping alumina on the electrical and sintering performances of yttrium-stabilized-zirconia , 2016 .

[166]  K. Engelbrecht,et al.  An Ag based brazing system with a tunable thermal expansion for the use as sealant for solid oxide cells , 2016 .

[167]  H. Frandsen,et al.  Efficient modeling of metallic interconnects for thermo-mechanical simulation of SOFC stacks: Homogenized behaviors and effect of contact , 2016 .

[168]  Sangtae Kim,et al.  Fast firing of bismuth doped yttria-stabilized zirconia for enhanced densification and ionic conductivity , 2016 .

[169]  H. Yoon,et al.  A methane-fueled SOFC based on a thin BaZr0.1Ce0.7Y0.1Yb0.1O3−δ electrolyte film and a LaNi0.6Co0.4O3 anode functional layer , 2016 .

[170]  Donglin Han,et al.  Strategy to improve phase compatibility between proton conductive BaZr0.8Y0.2O3−δ and nickel oxide , 2016 .

[171]  Kevin Huang,et al.  Remarkable O2 permeation through a mixed conducting carbon capture membrane functionalized by atomic layer deposition , 2016 .

[172]  P. Hendriksen,et al.  Assesment of (Mn,Co)33O4 powders for possible coating material for SOFC/SOEC interconnects , 2016 .

[173]  Mogens Bjerg Mogensen,et al.  Understanding degradation of solid oxide electrolysis cells through modeling of electrochemical potential profiles , 2016 .

[174]  Nigel P. Brandon,et al.  Carbon deposition behaviour in metal-infiltrated gadolinia doped ceria electrodes for simulated biogas upgrading in solid oxide electrolysis cells , 2015 .

[175]  F. Mauvy,et al.  Influence of pressure on solid oxide electrolysis cells investigated by experimental and modeling approach , 2015 .

[176]  A. Mahmood,et al.  High-performance solid oxide electrolysis cell based on ScSZ/GDC (scandia-stabilized zirconia/gadolinium-doped ceria) bi-layered electrolyte and LSCF (lanthanum strontium cobalt ferrite) oxygen electrode , 2015 .

[177]  B. Zhao,et al.  Preparation of ultra-fine Sm0.2Ce0.8O1.9 powder by a novel solid state reaction and fabrication of dense Sm0.2Ce0.8O1.9 electrolyte film , 2015 .

[178]  Francesco Ghigliazza,et al.  Production of synthesis gas (H2 and CO) by high-temperature Co-electrolysis of H2O and CO2 , 2015 .

[179]  S. Hyun,et al.  Effects of 8 mol% yttria-stabilized zirconia with copper oxide on solid oxide fuel cell performance , 2015 .

[180]  K. Kim,et al.  Effect of Ce0.43Zr0.43Gd0.1Y0.04O2−δ contact layer on stability of interface between GDC interlayer and YSZ electrolyte in solid oxide electrolysis cell , 2015 .

[181]  D. Mullins The surface chemistry of cerium oxide , 2015 .

[182]  Jiang Liu,et al.  An Investigation on Dip-Coating Technique for Fabricating Anode-Supported Solid Oxide Fuel Cells , 2015 .

[183]  Yu Luo,et al.  Carbon deposition on patterned nickel/yttria stabilized zirconia electrodes for solid oxide fuel cell/solid oxide electrolysis cell modes , 2015 .

[184]  M. Laguna-Bercero,et al.  Electrochemical Performance of Nd1.95NiO4+δ Cathode supported Microtubular Solid Oxide Fuel Cells , 2015 .

[185]  P. Hendriksen,et al.  Size of oxide vacancies in fluorite and perovskite structured oxides , 2015, Journal of Electroceramics.

[186]  T. Brylewski,et al.  Microstructure and electrical properties of Mn1+xCo2−xO4 (0≤x≤1.5) spinels synthesized using EDTA-gel processes , 2014 .

[187]  M. Arriortua,et al.  EB-PVD deposition of spinel coatings on metallic materials and silicon wafers , 2014 .

[188]  Dimitrios K. Niakolas,et al.  Sulfur poisoning of Ni-based anodes for Solid Oxide Fuel Cells in H/C-based fuels , 2014 .

[189]  Xiufu Sun,et al.  Durability of high performance Ni-yttria stabilized zirconia supported solid oxide electrolysis cells at high current density , 2014 .

[190]  G. Choi,et al.  Stability of LSCF electrode with GDC interlayer in YSZ-based solid oxide electrolysis cell , 2014 .

[191]  Yixiang Shi,et al.  Theoretical modeling of air electrode operating in SOFC mode and SOEC mode: The effects of microstructure and thickness , 2014 .

[192]  C. Xia,et al.  Chemically-induced mechanical unstability of samaria-doped ceria electrolyte for solid oxide electrolysis cells , 2014 .

[193]  M. Cassir,et al.  Solid oxide electrolysis cell analysis by means of electrochemical impedance spectroscopy: A review , 2014 .

[194]  Yixiang Shi,et al.  Comprehensive modeling of tubular solid oxide electrolysis cell for co-electrolysis of steam and carbon dioxide , 2014 .

[195]  Wei Zhang,et al.  Carbon Nanotube Growth on Nanozirconia under Strong Cathodic Polarization in Steam and Carbon Dioxide , 2014 .

[196]  Sun-Ju Song,et al.  Highly conductive barium zirconate-based carbonate composite electrolytes for intermediate temperature-protonic ceramic fuel cells , 2014 .

[197]  J. Ferreira,et al.  Aluminosilicate-based sealants for SOFCs and other electrochemical applications − A brief review , 2013 .

[198]  A. Galerie,et al.  Effect of Coatings on a Commercial Stainless Steel for SOEC Interconnect Application in Anode Atmosphere , 2013 .

[199]  Chakib Bouallou,et al.  Model-based behaviour of a high temperature electrolyser system operated at various loads , 2013 .

[200]  Yixiang Shi,et al.  Performance and methane production characteristics of H2O–CO2 co-electrolysis in solid oxide electrolysis cells , 2013 .

[201]  Nigel P. Brandon,et al.  A study of carbon deposition on solid oxide fuel cell anodes using electrochemical impedance spectroscopy in combination with a high temperature crystal microbalance , 2013 .

[202]  S. Bharadwaj,et al.  Physicochemical properties of rare earth doped ceria Ce0.9Ln0.1O1.95 (Ln = Nd, Sm, Gd) as an electrolyte material for IT-SOFC/SOEC , 2013 .

[203]  I. Chen,et al.  Electro‐Sintering of Yttria‐Stabilized Cubic Zirconia , 2013 .

[204]  Boxuan Yu,et al.  Preparation and electrochemical behavior of dense YSZ film for SOEC , 2012 .

[205]  Wei Yuan,et al.  Porous metal materials for polymer electrolyte membrane fuel cells – A review , 2012 .

[206]  Meng Ni,et al.  2D thermal modeling of a solid oxide electrolyzer cell (SOEC) for syngas production by H2O/CO2 co-electrolysis , 2012 .

[207]  Joongmyeon Bae,et al.  Electrochemical performance of solid oxide electrolysis cell electrodes under high-temperature coele , 2011 .

[208]  S. Ebbesen,et al.  Durable SOC stacks for production of hydrogen and synthesis gas by high temperature electrolysis , 2011 .

[209]  K. Prince,et al.  Electronic Structure of Magnesia−Ceria Model Catalysts, CO2 Adsorption, and CO2 Activation: A Synchrotron Radiation Photoelectron Spectroscopy Study , 2011 .

[210]  M. Nolan Formation of Ce3+ at the cerium dioxide (110) surface by doping , 2010 .

[211]  M. Mahapatra,et al.  Glass-based seals for solid oxide fuel and electrolyzer cells - A review , 2010 .

[212]  G. Bertrand,et al.  Suspension Plasma Spraying to Manufacture Electrodes for Solid Oxide Fuel Cell (SOFC) and Solid Oxide Electrolysis Cell (SOEC) , 2009 .

[213]  D. Leung,et al.  Technological development of hydrogen production by solid oxide electrolyzer cell (SOEC) , 2008 .

[214]  Wei Li,et al.  Novel Al2O3-based compressive seals for IT-SOFC applications , 2008 .

[215]  P. Dahl,et al.  Densification and properties of zirconia prepared by three different sintering techniques , 2007 .

[216]  S. Jensen,et al.  Hydrogen and synthetic fuel production from renewable energy sources , 2007 .

[217]  G. Meng,et al.  Fabrication and characterization of Y2O3 stabilized ZrO2 films deposited with aerosol-assisted MOCVD , 2007 .

[218]  Jeffrey W. Fergus,et al.  Sealants for solid oxide fuel cells , 2005 .

[219]  J. R. Jurado,et al.  Structure, Microstructure, and Mixed Conduction of [(ZrO2)0.92(Y2O3)0.08]0.9(TiO2)0.1 , 2002 .

[220]  A. Kovalevsky,et al.  Ceria-based materials for solid oxide fuel cells , 2001 .

[221]  G. Meng,et al.  Preparation of yttria stabilized zirconia membranes on porous substrates by a dip-coating process , 2000 .

[222]  M. Inagaki,et al.  Mechanical and electrical properties of Sc2O3-doped zirconia ceramics improved by postsintering with HIP , 2000 .

[223]  M. Watanabe,et al.  HIGH PERFORMANCE ELECTRODE FOR MEDIUM-TEMPERATURE SOLID OXIDE FUEL CELLS LA(SR)COO3 CATHODE WITH CERIA INTERLAYER ON ZIRCONIA ELECTROLYTE , 1999 .

[224]  Y. Takeda,et al.  Electrical conductivity of the ZrO2–Ln2O3 (Ln=lanthanides) system , 1999 .

[225]  Meihong Wang,et al.  Long-term performance prediction of solid oxide electrolysis cell (SOEC) for CO2/H2O co-electrolysis considering structural degradation through modelling and simulation , 2022, Chemical Engineering Journal.

[226]  Guojun Yu,et al.  Analysis of effects of meso-scale reactions on multiphysics transport processes in rSOFC fueled with syngas , 2020 .

[227]  Christoph Hochenauer,et al.  Characterization and performance study of commercially available solid oxide cell stacks for an autonomous system , 2020 .

[228]  A. Arpornwichanop,et al.  Flowsheet-based model and exergy analysis of solid oxide electrolysis cells for clean hydrogen production , 2018 .

[229]  Jun Woo Kim,et al.  High Performance Anode-Supported Solid Oxide Fuel Cells with Thin Film Yttria-Stabilized Zirconia Membrane Prepared by Aerosol-Assisted Chemical Vapor Deposition , 2017 .

[230]  Sun-Dong Kim,et al.  Densification of gadolinia-doped ceria diffusion barriers for SOECs and IT-SOFCs by a sol–gel process , 2016 .

[231]  Rak-Hyun Song,et al.  Fundamental mechanisms involved in the degradation of nickel–yttria stabilized zirconia (Ni–YSZ) anode during solid oxide fuel cells operation: A review , 2016 .

[232]  S. Jiang,et al.  Review—Materials Degradation of Solid Oxide Electrolysis Cells , 2016 .

[233]  Sun-Ju Song,et al.  Dependence of H2O/CO2 Co-Electrolysis Performance of SOEC on Microstructural and Thermodynamic Parameters , 2016 .

[234]  M. Viviani,et al.  BaCe0.85Y0.15O2.925 dense layer by wet powder spraying as electrolyte for SOFC/SOEC applications , 2015 .

[235]  S. Ebbesen,et al.  Carbon Deposition in Solid Oxide Cells during Co-Electrolysis of H2O and CO2 , 2014 .

[236]  A. Gotlieb,et al.  The progression of calcific aortic valve disease through injury, cell dysfunction, and disruptive biologic and physical force feedback loops. , 2013, Cardiovascular pathology : the official journal of the Society for Cardiovascular Pathology.

[237]  Joongmyeon Bae,et al.  Performance of solid oxide electrolysis cell having bi-layered electrolyte during steam electrolysis and carbon dioxide electrolysis , 2011 .

[238]  K. Lackner,et al.  Sustainable hydrocarbon fuels by recycling CO2 and H2O with renewable or nuclear energy , 2011 .