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R. Fuentes, Jake Farell, J. Weidner (2011)
Multimetallic Electrocatalysts of Pt, Ru, and Ir Supported on Anatase and Rutile TiO2 for Oxygen Evolution in an Acid EnvironmentElectrochemical and Solid State Letters, 14
Friedemann Hegge, Florian Lombeck, Edgar Ortiz, Luca Bohn, Miriam Holst, M. Kroschel, J. Hübner, M. Breitwieser, P. Strasser, S. Vierrath (2020)
Efficient and Stable Low Iridium Loaded Anodes for PEM Water Electrolysis Made Possible by Nanofiber InterlayersACS Applied Energy Materials
Steffen Czioska, A. Boubnov, D. Escalera‐López, J. Geppert, Alexandra Zagalskaya, Philipp Röse, E. Saraçi, V. Alexandrov, U. Krewer, S. Cherevko, J. Grunwaldt (2021)
Increased Ir–Ir Interaction in Iridium Oxide during the Oxygen Evolution Reaction at High Potentials Probed by Operando SpectroscopyACS Catalysis
S. Kumar, V. Himabindu (2019)
Hydrogen production by PEM water electrolysis – A reviewMaterials Science for Energy Technologies
S. Geiger, O. Kasian, A. Mingers, K. Mayrhofer, S. Cherevko (2017)
Stability limits of tin-based electrocatalyst supportsScientific Reports, 7
M. Suermann, T. Schmidt, F. Büchi (2018)
Comparing the kinetic activation energy of the oxygen evolution and reduction reactionsElectrochimica Acta
G. Silva, Seiti Venturini, Siyuan Zhang, Mario Löffler, C. Scheu, K. Mayrhofer, E. Ticianelli, S. Cherevko (2020)
Oxygen Evolution Reaction on Tin Oxides Supported Iridium Catalysts: Do We Need Dopants?, 7
S. Geiger, O. Kasian, M. Ledendecker, E. Pizzutilo, A. Mingers, W. Fu, Oscar Diaz-Morales, Zhizhong Li, T. Oellers, L. Fruchter, A. Ludwig, K. Mayrhofer, M. Koper, S. Cherevko (2018)
The stability number as a metric for electrocatalyst stability benchmarkingNature Catalysis, 1
S. Geiger, O. Kasian, A. Mingers, S. Nicley, K. Haenen, K. Mayrhofer, S. Cherevko (2017)
Catalyst Stability Benchmarking for the Oxygen Evolution Reaction: The Importance of Backing Electrode Material and Dissolution in Accelerated Aging Studies.ChemSusChem, 10 21
S. Alia, Mai-Anh Ha, Grace Anderson, C. Ngo, S. Pylypenko, R. Larsen (2019)
The Roles of Oxide Growth and Sub-Surface Facets in Oxygen Evolution Activity of Iridium and Its Impact on ElectrolysisJournal of The Electrochemical Society
Ailong Li, Hideshi Ooka, N. Bonnet, Toru Hayashi, Yimeng Sun, Qike Jiang, Can Li, Hongxian Han, Ryuhei Nakamura (2019)
Stable Potential Windows for Long-Term Electrocatalysis by Manganese Oxides Under Acidic Conditions.Angewandte Chemie, 58 15
(1986)
Electrode Kinetics: Principles and Methodology, Comprehensive Chemical Kinetics (Eds
Hyunki Kim, Junhyeong Kim, Joo-Yeob Kim, G. Han, W. Guo, Seokjin Hong, Hyun Park, Ho Jang, S. Kim, S. Ahn (2021)
Dendritic gold-supported iridium/iridium oxide ultra-low loading electrodes for high-performance proton exchange membrane water electrolyzerApplied Catalysis B-environmental, 283
P. Trinke, B. Bensmann, R. Hanke-Rauschenbach (2017)
Experimental evidence of increasing oxygen crossover with increasing current density during PEM water electrolysisElectrochemistry Communications, 82
M. Cha, Ji Park, Sungjun Kim, Seung-Hui Han, S. Shin, S. Yang, Tae-Ho Kim, D. Yu, Soonyong So, Y. Hong, S. Yoon, Seong-Geun Oh, S. Kang, Ok-Hee Kim, H. Park, Byungchan Bae, Y. Sung, Yong‐Hun Cho, J. Lee (2020)
Poly(carbazole)-based anion-conducting materials with high performance and durability for energy conversion devicesEnergy and Environmental Science, 13
Y. Kim (2021)
Polymer Electrolytes with High Ionic Concentration for Fuel Cells and Electrolyzers, 3
Alexandra Hartig-Weiss, Mohammad Tovini, H. Gasteiger, H. El-Sayed (2020)
OER Catalyst Durability Tests Using the Rotating Disk Electrode Technique: The Reason Why This Leads to Erroneous Conclusions, 3
Qi Feng, Xiao‐Zi Yuan, Gaoyang Liu, W. Bing, Zhen Zhang, Hui Li, Haijiang Wang (2017)
A review of proton exchange membrane water electrolysis on degradation mechanisms and mitigation strategiesJournal of Power Sources, 366
Aleksandar Zeradjanin, Ashokanand Vimalanandan, G. Polymeros, A. Topalov, K. Mayrhofer, M. Rohwerder (2017)
Balanced work function as a driver for facile hydrogen evolution reaction - comprehension and experimental assessment of interfacial catalytic descriptor.Physical chemistry chemical physics : PCCP, 19 26
Peter Holzapfel, M. Bühler, D. Escalera‐López, M. Bierling, F. Speck, K. Mayrhofer, S. Cherevko, Chuyen Pham, S. Thiele (2020)
Fabrication of a Robust PEM Water Electrolyzer Based on Non-Noble Metal Cathode Catalyst: [Mo3 S13 ]2- Clusters Anchored to N-Doped Carbon Nanotubes.Small
M. Debe (2012)
Nanostructured Thin Film Electrocatalysts for PEM Fuel Cells - A Tutorial on the Fundamental Characteristics and Practical Properties of NSTF Catalysts, 45
S. Siracusano, V. Baglio, E. Moukheiber, L. Merlo, A. Aricò (2015)
Performance of a PEM water electrolyser combining an IrRu-oxide anode electrocatalyst and a short-side chain Aquivion membraneInternational Journal of Hydrogen Energy, 40
B. Lee, S. Ahn, Hee-Young Park, Insoo Choi, S. Yoo, Hyoung‐Juhn Kim, D. Henkensmeier, J. Kim, Sehkyu Park, S. Nam, K. Lee, J. Jang (2015)
Development of electrodeposited IrO2 electrodes as anodes in polymer electrolyte membrane water electrolysisApplied Catalysis B-environmental, 179
Zhenye Kang, Jingke Mo, Gaoqiang Yang, S. Retterer, D. Cullen, T. Toops, Johney Green, M. Mench, Feng-Yuan Zhang (2017)
Investigation of thin/well-tunable liquid/gas diffusion layers exhibiting superior multifunctional performance in low-temperature electrolytic water splittingEnergy and Environmental Science, 10
T. Schmidt, H. Gasteiger, G. Staeb, P. Urbán, D. Kolb, R. Behm (1998)
Characterization of High‐Surface‐Area Electrocatalysts Using a Rotating Disk Electrode ConfigurationJournal of The Electrochemical Society, 145
B. Etzold, U. Krewer, S. Thiele, A. Dreizler, E. Klemm, T. Turek (2021)
Understanding the activity transport nexus in water and CO2 electrolysis: State of the art, challenges and perspectivesChemical Engineering Journal, 424
Ye Kim, Ahyoun Lim, Jong Kim, D. Lim, K. Chae, E. Cho, H. Han, Kiung Jeon, MooHyun Kim, Gun Lee, Gyu Lee, H. Ahn, H. Park, Hyoungsoo Kim, J. Kim, Y. Jung (2020)
Highly efficient oxygen evolution reaction via facile bubble transport realized by three-dimensionally stack-printed catalystsNature Communications, 11
Shuaiqi Zhao, A. Stocks, B. Rasimick, K. More, Hui Xu (2018)
Highly Active, Durable Dispersed Iridium Nanocatalysts for PEM Water ElectrolyzersJournal of The Electrochemical Society, 165
C. Minke, M. Suermann, B. Bensmann, R. Hanke-Rauschenbach (2021)
Is iridium demand a potential bottleneck in the realization of large-scale PEM water electrolysis?International Journal of Hydrogen Energy
Peter Holzapfel, M. Bühler, Chuyen Pham, Friedemann Hegge, T. Böhm, David McLaughlin, M. Breitwieser, S. Thiele (2020)
Directly coated membrane electrode assemblies for proton exchange membrane water electrolysisElectrochemistry Communications
W. Hong, M. Risch, K. Stoerzinger, A. Grimaud, Jin Suntivich, Y. Shao-horn (2015)
Toward the rational design of non-precious transition metal oxides for oxygen electrocatalysisEnergy and Environmental Science, 8
N. Mamaca, E. Mayousse, S. Arrii-Clacens, T. Napporn, K. Servat, N. Guillet, K. Kokoh (2012)
Electrochemical activity of ruthenium and iridium based catalysts for oxygen evolution reactionApplied Catalysis B-environmental, 111
S. Alia, S. Shulda, C. Ngo, S. Pylypenko, B. Pivovar (2018)
Iridium-Based Nanowires as Highly Active, Oxygen Evolution Reaction ElectrocatalystsACS Catalysis
Chang Liu, Meital Shviro, A. Gago, S. Zaccarine, G. Bender, P. Gazdzicki, T. Morawietz, I. Biswas, M. Rasinski, A. Everwand, R. Schierholz, Jason Pfeilsticker, Martin Müller, P. Lopes, R. Eichel, B. Pivovar, S. Pylypenko, K. Friedrich, W. Lehnert, M. Carmo (2021)
Exploring the Interface of Skin‐Layered Titanium Fibers for Electrochemical Water SplittingAdvanced Energy Materials, 11
C. Rozain, E. Mayousse, N. Guillet, P. Millet (2016)
Influence of iridium oxide loadings on the performance of PEM water electrolysis cells: Part I–Pure IrO2-based anodesApplied Catalysis B-environmental, 182
Huaneng Su, V. Linkov, B. Bladergroen (2013)
Membrane electrode assemblies with low noble metal loadings for hydrogen production from solid polymer electrolyte water electrolysisInternational Journal of Hydrogen Energy, 38
M. Carmo, D. Fritz, J. Mergel, D. Stolten (2013)
A comprehensive review on PEM water electrolysisInternational Journal of Hydrogen Energy, 38
Camila Silva, Fabien Claudel, V. Martin, Raphaël Chattot, Sofyane Abbou, Kavita Kumar, Ignacio Jiménez-Morales, S. Cavaliere, Deborah Jones, J. Roziere, Lluís Solà-Hernández, C. Beauger, M. Faustini, J. Peron, B. Gilles, Thierry Encinas, L. Piccolo, Fabio Lima, L. Dubau, F. Maillard (2021)
Oxygen Evolution Reaction Activity and Stability Benchmarks for Supported and Unsupported IrOx ElectrocatalystsACS Catalysis
Chuyen Pham, M. Bühler, Julius Knöppel, M. Bierling, D. Seeberger, D. Escalera‐López, K. Mayrhofer, S. Cherevko, S. Thiele (2020)
IrO2 coated TiO2 core-shell microparticles advance performance of low loading proton exchange membrane water electrolyzersApplied Catalysis B-environmental, 269
Hyung‐Suk Oh, Hong Nong, P. Strasser (2015)
Preparation of Mesoporous Sb‐, F‐, and In‐Doped SnO2 Bulk Powder with High Surface Area for Use as Catalyst Supports in Electrolytic CellsAdvanced Functional Materials, 25
A. Weiß, A. Siebel, M. Bernt, Tzu‐Hsien Shen, V. Tileli, H. Gasteiger (2018)
Impact of Intermittent Operation on Lifetime and Performance of a PEM Water ElectrolyzerJournal of The Electrochemical Society
C. Rozain, E. Mayousse, N. Guillet, P. Millet (2016)
Influence of iridium oxide loadings on the performance of PEM water electrolysis cells: Part II – Advanced oxygen electrodesApplied Catalysis B-environmental, 182
S. Alia, K. Hurst, S. Kocha, B. Pivovar (2016)
Mercury Underpotential Deposition to Determine Iridium and Iridium Oxide Electrochemical Surface AreasJournal of The Electrochemical Society, 163
Tobias Schuler, Joseph Ciccone, B. Krentscher, F. Marone, Christian Peter, T. Schmidt, F. Büchi (2019)
Hierarchically Structured Porous Transport Layers for Polymer Electrolyte Water ElectrolysisAdvanced Energy Materials, 10
Yichao Lin, Ziqi Tian, Lin-juan Zhang, Jingyuan Ma, Zheng Jiang, Benjamin Deibert, Ruixiang Ge, Liang Chen (2019)
Chromium-ruthenium oxide solid solution electrocatalyst for highly efficient oxygen evolution reaction in acidic mediaNature Communications, 10
C. Spöri, J. Kwan, A. Bonakdarpour, D. Wilkinson, P. Strasser (2017)
The Stability Challenges of Oxygen Evolving Catalysts: Towards a Common Fundamental Understanding and Mitigation of Catalyst Degradation.Angewandte Chemie, 56 22
Hans Becker, L. Castanheira, G. Hinds (2020)
Local measurement of current collector potential in a polymer electrolyte membrane water electrolyserJournal of Power Sources, 448
M. Chatti, J. Gardiner, M. Fournier, B. Johannessen, T. Williams, T. Gengenbach, Narendra Pai, Cuong Nguyen, D. Macfarlane, R. Hocking, A. Simonov (2019)
Intrinsically stable in situ generated electrocatalyst for long-term oxidation of acidic water at up to 80 °CNature Catalysis, 2
S. Siracusano, N. Dijk, E. Payne-Johnson, V. Baglio, A. Aricò (2015)
Nanosized IrOx and IrRuOx electrocatalysts for the O2 evolution reaction in PEM water electrolysersApplied Catalysis B-environmental, 164
S. Bratsch (1989)
Standard Electrode Potentials and Temperature Coefficients in Water at 298.15 KJournal of Physical and Chemical Reference Data, 18
S. Garbe, Ugljesa Babic, Elisabeth Nilsson, T. Schmidt, L. Gubler (2019)
Communication—Pt-Doped Thin Membranes for Gas Crossover Suppression in Polymer Electrolyte Water ElectrolysisJournal of The Electrochemical Society
R. Frydendal, E. Paoli, Brian Knudsen, B. Wickman, Paolo Malacrida, I. Stephens, I. Chorkendorff (2014)
Benchmarking the Stability of Oxygen Evolution Reaction Catalysts: The Importance of Monitoring Mass Losses, 1
Amin Daryaei, G. Miller, Jason Willey, S. Choudhury, Britannia Vondrasek, D. Kazerooni, Matthew Burtner, C. Mittelsteadt, J. Lesko, J. Riffle, J. Mcgrath (2017)
Synthesis and Membrane Properties of Sulfonated Poly(arylene ether sulfone) Statistical Copolymers for Electrolysis of Water: Influence of Meta- and Para-Substituted Comonomers.ACS applied materials & interfaces, 9 23
Jingke Mo, Z. Kang, S. Retterer, D. Cullen, T. Toops, Johney Green, M. Mench, Feng-Yuan Zhang (2016)
Discovery of true electrochemical reactions for ultrahigh catalyst mass activity in water splittingScience Advances, 2
Sofyane Abbou, Raphaël Chattot, V. Martin, Fabien Claudel, Lluís Solà-Hernández, C. Beauger, L. Dubau, F. Maillard (2020)
Manipulating the Corrosion Resistance of SnO2 Aerogels through Doping for Efficient and Durable Oxygen Evolution Reaction Electrocatalysis in Acidic MediaACS Catalysis, 10
Hong Nong, Lin Gan, E. Willinger, D. Teschner, P. Strasser (2014)
IrOx core-shell nanocatalysts for cost- and energy-efficient electrochemical water splittingChemical Science, 5
M. Suermann, T. Schmidt, F. Büchi (2016)
Cell Performance Determining Parameters in High Pressure Water ElectrolysisElectrochimica Acta, 211
S. Cherevko, S. Geiger, O. Kasian, N. Kulyk, Jan-Philipp Grote, A. Savan, B. Shrestha, S. Merzlikin, B. Breitbach, A. Ludwig, K. Mayrhofer (2016)
Oxygen and hydrogen evolution reactions on Ru, RuO2, Ir, and IrO2 thin film electrodes in acidic and alkaline electrolytes: A comparative study on activity and stabilityCatalysis Today, 262
Julius Knöppel, M. Möckl, D. Escalera‐López, K. Stojanovski, M. Bierling, T. Böhm, S. Thiele, M. Rzepka, S. Cherevko (2020)
On the limitations in assessing stability of oxygen evolution catalysts using aqueous model electrochemical cellsNature Communications, 12
O. Kasian, Tong Li, A. Mingers, K. Schweinar, A. Savan, A. Ludwig, K. Mayrhofer (2020)
Stabilization of an iridium oxygen evolution catalyst by titanium oxidesJournal of Physics: Energy, 3
M. Bernt, Alexandra Hartig-Weiss, Mohammad Tovini, H. El-Sayed, C. Schramm, J. Schröter, C. Gebauer, H. Gasteiger (2020)
Current Challenges in Catalyst Development for PEM Water ElectrolyzersChemie Ingenieur Technik
Chuanpu Hao, H. Lv, Qiang Zhao, Bing Li, Cunman Zhang, C. Mi, Yukun Song, J. Ma (2017)
Investigation of V-doped TiO2 as an anodic catalyst support for SPE water electrolysisInternational Journal of Hydrogen Energy, 42
Hong Nong, T. Reier, Hyung‐Suk Oh, Manuel Gliech, Paul Paciok, T. Vu, D. Teschner, M. Heggen, V. Petkov, R. Schlögl, T. Jones, P. Strasser (2018)
A unique oxygen ligand environment facilitates water oxidation in hole-doped IrNiOx core–shell electrocatalystsNature Catalysis, 1
(1989)
Levelized Cost of Energy , Levelized Cost of Storage , and Levelized Cost of Hydrogen DOE Technical Targets for Hydrogen Production from Electrolysis
C. Spöri, Cornelius Brand, M. Kroschel, P. Strasser (2021)
Accelerated Degradation Protocols for Iridium-Based Oxygen Evolving Catalysts in Water Splitting DevicesJournal of The Electrochemical Society
Oliver Schmidt, A. Gambhir, I. Staffell, A. Hawkes, J. Nelson, S. Few (2017)
Future cost and performance of water electrolysis: An expert elicitation studyInternational Journal of Hydrogen Energy, 42
S. Maaß, F. Finsterwalder, G. Frank, R. Hartmann, C. Merten (2008)
Carbon support oxidation in PEM fuel cell cathodesJournal of Power Sources, 176
J. Lopata, Zhenye Kang, James Young, Guido Bender, J. Weidner, S. Shimpalee (2020)
Effects of the Transport/Catalyst Layer Interface and Catalyst Loading on Mass and Charge Transport Phenomena in Polymer Electrolyte Membrane Water Electrolysis DevicesJournal of The Electrochemical Society, 167
P. Mazúr, J. Polonský, M. Paidar, K. Bouzek (2012)
Non-conductive TiO2 as the anode catalyst support for PEM water electrolysisInternational Journal of Hydrogen Energy, 37
Ugljesa Babic, M. Tarik, T. Schmidt, L. Gubler (2020)
Understanding the effects of material properties and operating conditions on component aging in polymer electrolyte water electrolyzersJournal of Power Sources, 451
B. Kim, Daniel Abbott, Xi Cheng, E. Fabbri, M. Nachtegaal, F. Bozza, I. Castelli, Dmitry Lebedev, R. Schäublin, C. Copéret, T. Graule, N. Marzari, T. Schmidt (2017)
Unraveling Thermodynamics, Stability, and Oxygen Evolution Activity of Strontium Ruthenium Perovskite OxideACS Catalysis, 7
Chuanpu Hao, H. Lv, C. Mi, Yukun Song, J. Ma (2016)
Investigation of Mesoporous Niobium-Doped TiO2 as an Oxygen Evolution Catalyst Support in an SPE Water ElectrolyzerACS Sustainable Chemistry & Engineering, 4
C. Klose, P. Trinke, T. Böhm, B. Bensmann, S. Vierrath, R. Hanke-Rauschenbach, S. Thiele (2018)
Membrane Interlayer with Pt Recombination Particles for Reduction of the Anodic Hydrogen Content in PEM Water ElectrolysisJournal of The Electrochemical Society, 165
Pia Aßmann, A. Gago, P. Gazdzicki, K. Friedrich, M. Wark (2020)
Toward developing accelerated stress tests for proton exchange membrane electrolyzersCurrent Opinion in Electrochemistry
Konrad Ehelebe, D. Escalera‐López, S. Cherevko (2021)
Limitations of aqueous model systems in the stability assessment of electrocatalysts for oxygen reactions in fuel cell and electrolysersCurrent Opinion in Electrochemistry
M. Suermann, B. Bensmann, R. Hanke-Rauschenbach (2019)
Degradation of Proton Exchange Membrane (PEM) Water Electrolysis Cells: Looking Beyond the Cell Voltage IncreaseJournal of The Electrochemical Society
H. Ohno, S. Nohara, K. Kakinuma, M. Uchida, H. Uchida (2018)
Effect of Electronic Conductivities of Iridium Oxide/Doped SnO2 Oxygen-Evolving Catalysts on the Polarization Properties in Proton Exchange Membrane Water ElectrolysisCatalysts
Haoran Yu, N. Danilovic, Yangbo Wang, W. Willis, A. Poozhikunnath, L. Bonville, Christopher Capuano, K. Ayers, R. Maric (2018)
Nano-size IrOx catalyst of high activity and stability in PEM water electrolyzer with ultra-low iridium loadingApplied Catalysis B: Environmental
Zhenye Kang, S. Alia, M. Carmo, G. Bender (2021)
In-situ and in-operando analysis of voltage losses using sense wires for proton exchange membrane water electrolyzersJournal of Power Sources, 481
N. Briguglio, S. Siracusano, G. Bonura, D. Sebastián, A. Aricò (2019)
Flammability reduction in a pressurised water electrolyser based on a thin polymer electrolyte membrane through a Pt-alloy catalytic approachApplied Catalysis B: Environmental
M. Bühler, Peter Holzapfel, David McLaughlin, S. Thiele (2019)
From Catalyst Coated Membranes to Porous Transport Electrode Based Configurations in PEM Water ElectrolyzersJournal of The Electrochemical Society
Tobias Schuler, T. Schmidt, F. Büchi (2019)
Polymer Electrolyte Water Electrolysis: Correlating Performance and Porous Transport Layer Structure: Part II. Electrochemical Performance AnalysisJournal of The Electrochemical Society
Yubo Chen, Haiyan Li, Jingxian Wang, Yonghua Du, S. Xi, Yuanmiao Sun, M. Sherburne, J. Ager, A. Fisher, Zhichuan Xu (2019)
Exceptionally active iridium evolved from a pseudo-cubic perovskite for oxygen evolution in acidNature Communications, 10
Ahyoun Lim, Jun-young Kim, Hyekyung Lee, Hyoung‐Juhn Kim, S. Yoo, J. Jang, H. Park, Y. Sung, H. Park (2020)
Low-loading IrO2 supported on Pt for catalysis of PEM water electrolysis and regenerative fuel cellsApplied Catalysis B-environmental, 272
D. Escalera‐López, Steffen Czioska, J. Geppert, A. Boubnov, Philipp Röse, E. Saraçi, U. Krewer, J. Grunwaldt, S. Cherevko (2021)
Phase- and Surface Composition-Dependent Electrochemical Stability of Ir-Ru Nanoparticles during Oxygen Evolution ReactionACS Catalysis
Daniel Abbott, Dmitry Lebedev, Kay Waltar, M. Povia, M. Nachtegaal, E. Fabbri, C. Copéret, T. Schmidt (2016)
Iridium Oxide for the Oxygen Evolution Reaction: Correlation between Particle Size, Morphology, and the Surface Hydroxo Layer from Operando XASChemistry of Materials, 28
J. Vos, Zhichao Liu, F. Speck, N. Perini, Wentian Fu, S. Cherevko, M. Koper (2019)
Selectivity Trends Between Oxygen Evolution and Chlorine Evolution on Iridium-Based Double Perovskites in Acidic MediaACS Catalysis
P. Trinke, B. Bensmann, R. Hanke-Rauschenbach (2017)
Current density effect on hydrogen permeation in PEM water electrolyzersInternational Journal of Hydrogen Energy, 42
R. Adams, R. Shriner (1923)
PLATINUM OXIDE AS A CATALYST IN THE REDUCTION OF ORGANIC COMPOUNDS. III. PREPARATION AND PROPERTIES OF THE OXIDE OF PLATINUM OBTAINED BY THE FUSION OF CHLOROPLATINIC ACID WITH SODIUM NITRATE1Journal of the American Chemical Society, 45
Chao Wei, Reshma Rao, Jiayu Peng, Botao Huang, I. Stephens, M. Risch, Zhichuan Xu, Y. Shao-horn (2019)
Recommended Practices and Benchmark Activity for Hydrogen and Oxygen Electrocatalysis in Water Splitting and Fuel CellsAdvanced Materials, 31
E. Brightman, J. Dodwell, Nick Dijk, G. Hinds (2015)
In situ characterisation of PEM water electrolysers using a novel reference electrode.Electrochemistry Communications, 52
Friedemann Hegge, R. Moroni, P. Trinke, B. Bensmann, R. Hanke-Rauschenbach, S. Thiele, S. Vierrath (2018)
Three-dimensional microstructure analysis of a polymer electrolyte membrane water electrolyzer anodeJournal of Power Sources
Emma Oakton, Dmitry Lebedev, A. Fedorov, F. Krumeich, J. Tillier, O. Sereda, T. Schmidt, C. Copéret (2016)
A simple one-pot Adams method route to conductive high surface area IrO2–TiO2 materialsNew Journal of Chemistry, 40
G. Silva, N. Perini, E. Ticianelli (2017)
Effect of temperature on the activities and stabilities of hydrothermally prepared IrOx nanocatalyst layers for the oxygen evolution reactionApplied Catalysis B-environmental, 218
Ji Yoo, Heejong Shin, Subin Park, Y. Sung (2021)
Recent progress in in situ/operando analysis tools for oxygen electrocatalysisJournal of Physics D: Applied Physics, 54
S. Siracusano, A. Blasi, V. Baglio, G. Brunaccini, N. Briguglio, A. Stassi, R. Ornelas, E. Trifoni, V. Antonucci, A. Aricò (2011)
Optimization of components and assembling in a PEM electrolyzer stackFuel and Energy Abstracts
Youngmi Yi, G. Weinberg, M. Prenzel, M. Greiner, Saskia Heumann, Sylvia Becker, R. Schlögl (2017)
Electrochemical corrosion of a glassy carbon electrodeCatalysis Today, 295
Sebastian Watzele, A. Bandarenka (2016)
Quick Determination of Electroactive Surface Area of Some Oxide Electrode MaterialsElectroanalysis, 28
Michael Huynh, Chenyang Shi, S. Billinge, D. Nocera (2015)
Nature of Activated Manganese Oxide for Oxygen Evolution.Journal of the American Chemical Society, 137 47
T. Bligaard, R. Bullock, C. Campbell, Jing Chen, B. Gates, R. Gorte, Christopher Jones, W. Jones, J. Kitchin, S. Scott (2016)
Toward Benchmarking in Catalysis Science: Best Practices, Challenges, and OpportunitiesACS Catalysis, 6
V. Streibel, M. Hävecker, Youngmi Yi, J. Vélez, K. Skorupska, Eugen Stotz, A. Knop‐Gericke, R. Schlögl, Rosa Arrigo (2018)
In Situ Electrochemical Cells to Study the Oxygen Evolution Reaction by Near Ambient Pressure X-ray Photoelectron SpectroscopyTopics in Catalysis, 61
H. El-Sayed, A. Weiß, Lorenz Olbrich, Garin Putro, H. Gasteiger (2019)
OER Catalyst Stability Investigation Using RDE Technique: A Stability Measure or an Artifact?Journal of The Electrochemical Society
Seunghoe Choe, B. Lee, M. Cho, Hyoung‐Juhn Kim, D. Henkensmeier, S. Yoo, J. Kim, So Lee, H. Park, J. Jang (2018)
Electrodeposited IrO2/Ti electrodes as durable and cost-effective anodes in high-temperature polymer-membrane-electrolyte water electrolyzersApplied Catalysis B: Environmental
Haoran Yu, L. Bonville, J. Jankovic, R. Maric (2020)
Microscopic insights on the degradation of a PEM water electrolyzer with ultra-low catalyst loadingApplied Catalysis B-environmental, 260
Ugljesa Babic, M. Suermann, F. Büchi, L. Gubler, T. Schmidt (2017)
Critical Review—Identifying Critical Gaps for Polymer Electrolyte Water Electrolysis DevelopmentJournal of The Electrochemical Society, 164
Christoph Rakousky, U. Reimer, K. Wippermann, M. Carmo, W. Lueke, D. Stolten (2016)
An analysis of degradation phenomena in polymer electrolyte membrane water electrolysisJournal of Power Sources, 326
J. Roller, Siwon Kim, Tony Kwak, Haoran Yu, R. Maric (2017)
A study on the effect of selected process parameters in a jet diffusion flame for Pt nanoparticle formationJournal of Materials Science, 52
Alexandra Hartig-Weiss, Melanie Miller, Hans Beyer, Alexander Schmitt, A. Siebel, Anna Freiberg, H. Gasteiger, H. El-Sayed (2020)
Iridium Oxide Catalyst Supported on Antimony-Doped Tin Oxide for High Oxygen Evolution Reaction Activity in Acidic Media, 3
Emma Oakton, Dmitry Lebedev, M. Povia, Daniel Abbott, E. Fabbri, A. Fedorov, M. Nachtegaal, C. Copéret, T. Schmidt (2017)
IrO2-TiO2: A High-Surface-Area, Active, and Stable Electrocatalyst for the Oxygen Evolution ReactionACS Catalysis, 7
B. Pivovar, Neha Rustagi, S. Satyapal (2018)
Hydrogen at Scale (H 2 @Scale): Key to a Clean, Economic, and Sustainable Energy SystemThe Electrochemical Society interface, 27
G. Bender, M. Carmo, T. Smolinka, A. Gago, N. Danilovic, Martin Mueller, F. Ganci, A. Fallisch, P. Lettenmeier, K. Friedrich, K. Ayers, B. Pivovar, J. Mergel, D. Stolten (2019)
Initial approaches in benchmarking and round robin testing for proton exchange membrane water electrolyzersInternational Journal of Hydrogen Energy
O. Kasian, Jan-Philipp Grote, S. Geiger, S. Cherevko, K. Mayrhofer (2018)
The Common Intermediates of Oxygen Evolution and Dissolution Reactions during Water Electrolysis on IridiumAngewandte Chemie (International Ed. in English), 57
S. Siracusano, V. Baglio, N. Dijk, L. Merlo, A. Aricò (2017)
Enhanced performance and durability of low catalyst loading PEM water electrolyser based on a short-side chain perfluorosulfonic ionomerApplied Energy, 192
J. Dodwell, M. Maier, J. Majasan, R. Jervis, L. Castanheira, P. Shearing, G. Hinds, D. Brett (2021)
Open-circuit dissolution of platinum from the cathode in polymer electrolyte membrane water electrolysersJournal of Power Sources
H. Lv, Sen Wang, Chuanpu Hao, Wei Zhou, Jiakun Li, Mingzhe Xue, Cunman Zhang (2019)
Oxygen‐Deficient Ti0.9Nb0.1O2‐x as an Efficient Anodic Catalyst Support for PEM Water ElectrolyzerChemCatChem, 11
Thomas Audichon, E. Mayousse, S. Morisset, C. Morais, C. Comminges, T. Napporn, K. Kokoh (2014)
Electroactivity of RuO2–IrO2 mixed nanocatalysts toward the oxygen evolution reaction in a water electrolyzer supplied by a solar profileInternational Journal of Hydrogen Energy, 39
Nano Mater
K. Ayers, N. Danilovic, Ryan Ouimet, M. Carmo, B. Pivovar, Marius Bornstein (2019)
Perspectives on Low-Temperature Electrolysis and Potential for Renewable Hydrogen at Scale.Annual review of chemical and biomolecular engineering, 10
U. Paulus, T. Schmidt, H. Gasteiger, R. Behm (2001)
Oxygen reduction on a high-surface area Pt/Vulcan carbon catalyst: a thin-film rotating ring-disk electrode studyJournal of Electroanalytical Chemistry, 495
Sebastian Watzele, P. Hauenstein, Yunchang Liang, Song Xue, J. Fichtner, Batyr Garlyyev, Daniel Scieszka, Fabien Claudel, F. Maillard, A. Bandarenka (2019)
Determination of Electroactive Surface Area of Ni-, Co-, Fe-, and Ir-Based Oxide ElectrocatalystsACS Catalysis
C. Klose, Torben Saatkamp, A. Münchinger, Luca Bohn, G. Titvinidze, M. Breitwieser, K. Kreuer, S. Vierrath (2020)
All‐Hydrocarbon MEA for PEM Water Electrolysis Combining Low Hydrogen Crossover and High EfficiencyAdvanced Energy Materials, 10
D. Chung, Subin Park, P. Lopes, V. Stamenkovic, Y. Sung, N. Markovic, D. Strmcnik (2020)
Electrokinetic Analysis of Poorly Conductive Electrocatalytic MaterialsACS Catalysis, 10
Mohammad Tovini, Alexandra Hartig-Weiss, H. Gasteiger, H. El-Sayed (2021)
The Discrepancy in Oxygen Evolution Reaction Catalyst Lifetime Explained: RDE vs MEA - Dynamicity within the Catalyst Layer MattersJournal of The Electrochemical Society
Hong Nong, L. Falling, A. Bergmann, Malte Klingenhof, H. Tran, C. Spöri, R. Mom, J. Timoshenko, Guido Zichittella, A. Knop‐Gericke, S. Piccinin, J. Pérez–Ramírez, B. Cuenya, R. Schlögl, P. Strasser, D. Teschner, T. Jones (2020)
Key role of chemistry versus bias in electrocatalytic oxygen evolutionNature, 587
F. Pantò, S. Siracusano, N. Briguglio, A. Aricò (2020)
Durability of a recombination catalyst-based membrane-electrode assembly for electrolysis operation at high current densityApplied Energy, 279
S. Anantharaj, S. Noda, M. Driess, P. Menezes (2021)
The Pitfalls of Using Potentiodynamic Polarization Curves for Tafel Analysis in Electrocatalytic Water SplittingACS energy letters
Charles McCrory, Suho Jung, Ivonne Ferrer, S. Chatman, J. Peters, T. Jaramillo (2015)
Benchmarking hydrogen evolving reaction and oxygen evolving reaction electrocatalysts for solar water splitting devices.Journal of the American Chemical Society, 137 13
S. Siracusano, N. Hodnik, P. Jovanovič, F. Ruiz-Zepeda, Martin Šala, V. Baglio, A. Aricò (2017)
New insights into the stability of a high performance nanostructured catalyst for sustainable water electrolysisNano Energy, 40
K. Ayers, J. Renner, N. Danilovic, Jia Wang, Yu Zhang, R. Maric, Haoran Yu (2016)
Pathways to ultra-low platinum group metal catalyst loading in proton exchange membrane electrolyzersCatalysis Today, 262
Gaoqiang Yang, Shule Yu, Jingke Mo, Zhenye Kang, Yeshi Dohrmann, F. List, Johney Green, S. Babu, Feng-Yuan Zhang (2018)
Bipolar plate development with additive manufacturing and protective coating for durable and high-efficiency hydrogen productionJournal of Power Sources
McKenzie Hubert, Anjli Patel, A. Gallo, Yunzhi Liu, E. Valle, Micha Ben‐Naim, Joel Sanchez, D. Sokaras, R. Sinclair, J. Nørskov, Laurie King, M. Bajdich, T. Jaramillo (2020)
Acidic Oxygen Evolution Reaction Activity–Stability Relationships in Ru-Based PyrochloresACS Catalysis
Zachary Taie, Xiong Peng, D. Kulkarni, I. Zenyuk, A. Weber, C. Hagen, N. Danilovic (2020)
Pathway to Complete Energy Sector Decarbonization with Available Iridium Resources using Ultralow Loaded Water Electrolyzers.ACS applied materials & interfaces
M. Bernt, M. Singer, H. Gasteiger (2017)
Analysis of Voltage Losses in PEM Water Electrolyzers with Low Platinum Group Metal Loadings
R. Clémençon (2016)
The Two Sides of the Paris Climate AgreementThe Journal of Environment & Development, 25
Zhenye Kang, Gaoqiang Yang, Jingke Mo, Shule Yu, D. Cullen, S. Retterer, T. Toops, M. Brady, G. Bender, B. Pivovar, Johney Green, Feng-Yuan Zhang (2018)
Developing titanium micro/nano porous layers on planar thin/tunable LGDLs for high-efficiency hydrogen productionInternational Journal of Hydrogen Energy
M. Bernt, H. Gasteiger (2016)
Influence of Ionomer Content in IrO 2 /TiO 2 Electrodes on PEM Water Electrolyser Performance
Thomas Audichon, E. Mayousse, T. Napporn, C. Morais, C. Comminges, K. Kokoh (2014)
Elaboration and characterization of ruthenium nano-oxides for the oxygen evolution reaction in a Proton Exchange Membrane Water Electrolyzer supplied by a solar profileElectrochimica Acta, 132
Viktor Čolić, Jakub Tymoczko, Artjom Maljusch, Alberto Ganassin, W. Schuhmann, A. Bandarenka (2015)
Experimental Aspects in Benchmarking of the Electrocatalytic Activity, 2
L. Seitz, Colin Dickens, K. Nishio, Y. Hikita, Joseph Montoya, Andrew Doyle, Charlotte Kirk, A. Vojvodić, H. Hwang, J. Nørskov, T. Jaramillo (2016)
A highly active and stable IrOx/SrIrO3 catalyst for the oxygen evolution reactionScience, 353
Advanced Energy Materials – Wiley
Published: Nov 1, 2021
Keywords: catalyst layers; electrocatalysis; electrode design; hydrogen production; membrane electrode assembly; oxygen evolution reaction; PEM water electrolyzers
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