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References (84)
-
Zhenbin Wang, Ya-Rong Zheng, I. Chorkendorff, J. Nørskov (2020)
Acid-Stable Oxides for Oxygen ElectrocatalysisACS energy letters, 5
-
S. Geiger, O. Kasian, B. Shrestha, A. Mingers, K. Mayrhofer, S. Cherevko (2016)
Activity and stability of electrochemically and thermally treated iridium for the oxygen evolution reactionJournal of The Electrochemical Society, 163
-
C. Spöri, P. Briois, Hong Nong, T. Reier, A. Billard, S. Kühl, D. Teschner, P. Strasser (2019)
Experimental Activity Descriptors for Iridium-Based Catalysts for the Electrochemical Oxygen Evolution Reaction (OER)ACS Catalysis
-
Dr Rooij (2003)
Electrochemical Methods: Fundamentals and ApplicationsAnti-corrosion Methods and Materials, 50
-
S. Cherevko, Aleksandar Zeradjanin, A. Topalov, N. Kulyk, I. Katsounaros, K. Mayrhofer (2014)
Dissolution of Noble Metals during Oxygen Evolution in Acidic MediaChemCatChem, 6
-
S. Chu, A. Majumdar (2012)
Opportunities and challenges for a sustainable energy futureNature, 488
-
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
-
G. Stevens, T. Edmonds (1975)
Electron spectroscopy for chemical analysis spectra of molybdenum sulfidesJournal of Catalysis, 37
-
Daniel Merki, H. Vrubel, L. Rovelli, S. Fierro, Xile Hu (2012)
Fe, Co, and Ni ions promote the catalytic activity of amorphous molybdenum sulfide films for hydrogen evolutionChemical Science, 3
-
M. Chandrasekar, M. Pushpavanam (2008)
Pulse and pulse reverse plating—Conceptual,advantages and applicationsElectrochimica Acta, 53
-
S. Tan, M. Pumera (2017)
Electrosynthesis of Bifunctional WS3-x /Reduced Graphene Oxide Hybrid for Hydrogen Evolution Reaction and Oxygen Reduction Reaction Electrocatalysis.Chemistry, 23 35
-
H. Wang, P. Skeldon, G. Thompson (1997)
XPS studies of MoS2 formation from ammonium tetrathiomolybdate solutionsSurface & Coatings Technology, 91
-
P. Sebastián-Pascual, Inês Pereira, María Escudero‐Escribano (2020)
Tailored electrocatalysts by controlled electrochemical deposition and surface nanostructuring.Chemical communications
-
S. Gottesfeld, S. Srinivasan (1978)
Electrochemical and optical studies of thick oxide layers on iridium and their electrocatalytic activities for the oxygen evolution reactionJournal of Electroanalytical Chemistry, 86
-
S. Tan, M. Pumera (2016)
Bottom-up Electrosynthesis of Highly Active Tungsten Sulfide (WS3-x) Films for Hydrogen Evolution.ACS applied materials & interfaces, 8 6
-
Jaemin Kim, Pei‐Chieh Shih, Kai‐Chieh Tsao, Y. Pan, X. Yin, Cheng-Jun Sun, Hong Yang (2017)
High-Performance Pyrochlore-Type Yttrium Ruthenate Electrocatalyst for Oxygen Evolution Reaction in Acidic Media.Journal of the American Chemical Society, 139 34
-
W. Gruenert, A. Stakheev, R. Feldhaus, K. Anders, E. Shpiro, K. Minachev (1991)
Analysis of molybdenum(3d) XPS spectra of supported molybdenum catalysts: an alternative approachThe Journal of Physical Chemistry, 95
-
D. Escalera‐López, Z. Lou, N. Rees (2019)
Benchmarking the Activity, Stability, and Inherent Electrochemistry of Amorphous Molybdenum Sulfide for Hydrogen ProductionAdvanced Energy Materials, 9
-
Muhammad Nasir, Zdenek Sofer, M. Pumera (2015)
Effect of Electrolyte pH on the Inherent Electrochemistry of Layered Transition‐Metal Dichalcogenides (MoS2, MoSe2, WS2, WSe2), 2
-
Alaina Strickler, Raul Flores, Laurie King, J. Nørskov, M. Bajdich, T. Jaramillo (2019)
Systematic Investigation of Iridium-Based Bimetallic Thin Film Catalysts for the Oxygen Evolution Reaction in Acidic Media.ACS applied materials & interfaces
-
Anders Jensen, G. Sievers, K. Jensen, J. Quinson, José Arminio‐Ravelo, V. Brüser, M. Arenz, María Escudero‐Escribano (2020)
Self-supported nanostructured iridium-based networks as highly active electrocatalysts for oxygen evolution in acidic mediaJournal of Materials Chemistry, 8
-
Sunita Sharma, S. Ghoshal (2015)
Hydrogen the future transportation fuel: From production to applicationsRenewable & Sustainable Energy Reviews, 43
-
T. Reier, D. Teschner, T. Lunkenbein, A. Bergmann, S. Selve, R. Kraehnert, R. Schlögl, P. Strasser (2014)
Electrocatalytic Oxygen Evolution on Iridium Oxide: Uncovering Catalyst-Substrate Interactions and Active Iridium Oxide SpeciesJournal of The Electrochemical Society, 161
-
P. Vesborg, T. Jaramillo (2012)
Addressing the terawatt challenge: scalability in the supply of chemical elements for renewable energyRSC Advances, 2
-
Min Zhou, J. Dick, A. Bard (2017)
Electrodeposition of Isolated Platinum Atoms and Clusters on Bismuth-Characterization and Electrocatalysis.Journal of the American Chemical Society, 139 48
-
Daniel Merki, S. Fierro, H. Vrubel, Xile Hu (2011)
Amorphous molybdenum sulfide films as catalysts for electrochemical hydrogen production in waterChemical Science, 2
-
T. Reier, Hong Nong, D. Teschner, R. Schlögl, P. Strasser (2017)
Electrocatalytic Oxygen Evolution Reaction in Acidic Environments – Reaction Mechanisms and CatalystsAdvanced Energy Materials, 7
-
T. Reier, M. Oezaslan, P. Strasser (2012)
Electrocatalytic Oxygen Evolution Reaction (OER) on Ru, Ir, and Pt Catalysts: A Comparative Study of Nanoparticles and Bulk MaterialsACS Catalysis, 2
-
E. Fabbri, T. Schmidt (2018)
Oxygen Evolution Reaction—The Enigma in Water ElectrolysisACS Catalysis
-
Tim Weber, Till Ortmann, D. Escalera‐López, Marcel Abb, B. Mogwitz, S. Cherevko, M. Rohnke, H. Over (2020)
Visualizing Potential‐Induced Pitting Corrosion of Ultrathin Single‐Crystalline IrO2(110) Films on RuO2(110)/Ru(0001) under Electrochemical Water Splitting ConditionsChemCatChem, 12
-
H. Vrubel, Xile Hu (2013)
Growth and Activation of an Amorphous Molybdenum Sulfide Hydrogen Evolving CatalystACS Catalysis, 3
-
Alex Eng, A. Ambrosi, Zdenek Sofer, P. Šimek, M. Pumera (2014)
Electrochemistry of transition metal dichalcogenides: strong dependence on the metal-to-chalcogen composition and exfoliation method.ACS nano, 8 12
-
S. Back, Kevin Tran, Zachary Ulissi (2020)
Discovery of Acid-Stable Oxygen Evolution Catalysts: High-Throughput Computational Screening of Equimolar Bimetallic Oxides.ACS applied materials & interfaces
-
María Escudero‐Escribano, A. Pedersen, E. Paoli, R. Frydendal, D. Friebel, Paolo Malacrida, J. Rossmeisl, I. Stephens, I. Chorkendorff (2017)
Importance of Surface IrOx in Stabilizing RuO2 for Oxygen Evolution.The journal of physical chemistry. B, 122 2
-
P. Jovanovič, N. Hodnik, F. Ruiz-Zepeda, I. Arčon, Barbara Jozinović, M. Zorko, M. Bele, Martin Šala, V. Šelih, S. Hočevar, M. Gaberšček (2017)
Electrochemical Dissolution of Iridium and Iridium Oxide Particles in Acidic Media: Transmission Electron Microscopy, Electrochemical Flow Cell Coupled to Inductively Coupled Plasma Mass Spectrometry, and X-ray Absorption Spectroscopy Study.Journal of the American Chemical Society, 139 36
-
N. Danilovic, Ram Subbaraman, Kee-Chul Chang, Seo Chang, Yijin Kang, J. Snyder, A. Paulikas, D. Strmcnik, Yong‐Tae Kim, D. Myers, V. Stamenkovic, N. Markovic (2014)
Activity-Stability Trends for the Oxygen Evolution Reaction on Monometallic Oxides in Acidic Environments.The journal of physical chemistry letters, 5 14
-
I. Staffell, Daniel Scamman, Anthony Abad, P. Balcombe, P. Dodds, P. Ekins, N. Shah, K. Ward (2019)
The role of hydrogen and fuel cells in the global energy systemEnergy & Environmental Science
-
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
-
A. Katrib, F. Hemming, P. Wehrer, L. Hilaire, G. Maire (1995)
The multi-surface structure and catalytic properties of partially reduced WO3, WO2 and WC + O2 or W + O2 as characterized by XPSJournal of Electron Spectroscopy and Related Phenomena, 76
-
J. Juodkazytė, B. Šebeka, I. Valsiūnas, K. Juodkazis (2005)
Iridium Anodic Oxidation to Ir(III) and Ir(IV) Hydrous OxidesElectroanalysis, 17
-
M. Petit, V. Plichon (1998)
Anodic electrodeposition of iridium oxide filmsJournal of Electroanalytical Chemistry, 444
-
S. Alia, S. Shulda, C. Ngo, S. Pylypenko, B. Pivovar (2018)
Iridium-Based Nanowires as Highly Active, Oxygen Evolution Reaction ElectrocatalystsACS Catalysis
-
Hyung‐Suk Oh, Hong Nong, T. Reier, Manuel Gliech, P. Strasser (2015)
Oxide-supported Ir nanodendrites with high activity and durability for the oxygen evolution reaction in acid PEM water electrolyzers† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c5sc00518c Click here for additional data file.Chemical Science, 6
-
D. Escalera‐López, Ross Griffin, M. Isaacs, K. Wilson, R. Palmer, N. Rees (2017)
Electrochemical sulfidation of WS2 nanoarrays: Strong dependence of hydrogen evolution activity on transition metal sulfide surface compositionElectrochemistry Communications, 81
-
M. Carmo, D. Fritz, J. Mergel, D. Stolten (2013)
A comprehensive review on PEM water electrolysisInternational Journal of Hydrogen Energy, 38
-
Jiyeon Kim, J. Dick, A. Bard (2016)
Advanced Electrochemistry of Individual Metal Clusters Electrodeposited Atom by Atom to Nanometer by Nanometer.Accounts of chemical research, 49 11
-
K. Zeng, Dongke Zhang (2010)
Recent progress in alkaline water electrolysis for hydrogen production and applicationsProgress in Energy and Combustion Science, 36
-
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
-
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
-
K. Kondo, Y. Ikeda, M. Yokoi (2015)
Electrodeposited Copper Wire Mesh Formed on Chromium Template, the Formation Mechanism and Application as a Transparent Conductive FilmJournal of The Electrochemical Society, 162
-
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
-
R. Kötz, C. Barbero, O. Haas (1990)
PROBE BEAM DEFLECTION INVESTIGATION OF THE CHARGE STORAGE REACTION IN ANODIC IRIDIUM AND TUNGSTEN OXIDE FILMSJournal of Electroanalytical Chemistry, 296
-
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
-
Electrochem -
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
-
V. Pfeifer, T. Jones, J. Vélez, C. Massué, Rosa Arrigo, D. Teschner, F. Girgsdies, M. Scherzer, M. Greiner, J. Allan, M. Hashagen, G. Weinberg, S. Piccinin, M. Hävecker, A. Knop‐Gericke, R. Schlögl (2016)
The electronic structure of iridium and its oxidesSurface and Interface Analysis, 48
-
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
-
D. Böhm, M. Beetz, M. Schuster, K. Peters, A. Hufnagel, M. Döblinger, B. Böller, T. Bein, D. Fattakhova‐Rohlfing (2019)
Efficient OER Catalyst with Low Ir Volume Density Obtained by Homogeneous Deposition of Iridium Oxide Nanoparticles on Macroporous Antimony‐Doped Tin Oxide SupportAdvanced Functional Materials, 30
-
B. Vanrenterghem, M. Bele, F. Zepeda, Martin Šala, N. Hodnik, T. Breugelmans (2018)
Cutting the Gordian Knot of electrodeposition via controlled cathodic corrosion enabling the production of supported metal nanoparticles below 5 nmApplied Catalysis B: Environmental
-
I. Fonseca, M. Lopes, M. Portela (1996)
A comparative voltammetric study of the ir¦h2so4 and ir¦hclo4 aqueous interfacesJournal of Electroanalytical Chemistry, 415
-
I. Katsounaros, S. Cherevko, Aleksandar Zeradjanin, K. Mayrhofer (2014)
Oxygen electrochemistry as a cornerstone for sustainable energy conversion.Angewandte Chemie, 53 1
-
T. Reier, Zarina Pawolek, S. Cherevko, M. Bruns, T. Jones, D. Teschner, S. Selve, A. Bergmann, Hong Nong, R. Schlögl, K. Mayrhofer, P. Strasser (2015)
Molecular Insight in Structure and Activity of Highly Efficient, Low-Ir Ir-Ni Oxide Catalysts for Electrochemical Water Splitting (OER).Journal of the American Chemical Society, 137 40
-
S. Cherevko, S. Geiger, O. Kasian, A. Mingers, K. Mayrhofer (2016)
Oxygen evolution activity and stability of iridium in acidic media. Part 2. – Electrochemically grown hydrous iridium oxideJournal of Electroanalytical Chemistry, 774
-
S. Ardo, David Rivas, Miguel Modestino, Verena Greiving, F. Abdi, Esther Alarcon, Vincent Artero, Katherine Ayers, C. Battaglia, Jan-Philipp Becker, Dmytro Bederak, Alan Berger, Francesco Buda, E. Chinello, Bernard Dam, O. Valerio, Di Palma, T. Edvinsson, Katsushi Fujii, H. Gardeniers, H. Geerlings, S. Mohammad, H. Hashemi, S. Haussener, Frances Houle, J. Huskens, Brian James, Kornelia Konrad, Akihiko Kudo, Pramod Patil, Kunturu, Detlef Lohse, Bastian Mei, Eric Miller, Gary Moore, Jiri Muller, Katherine Orchard, Timothy Rosser, Fadl Saadi, J. Schüttauf, B. Seger, Stafford Sheehan, Wilson Smith, J. Spurgeon, Maureen Tang, R. Krol, Peter ag, P. Westerik (2018)
Pathways to electrochemical solar-hydrogen technologiesEnergy and Environmental Science, 11
-
H. Miller, K. Bouzek, Jaromír Hnát, Stefan Loos, C. Bernäcker, T. Weissgärber, L. Röntzsch, J. Meier-Haack (2020)
Green hydrogen from anion exchange membrane water electrolysis: a review of recent developments in critical materials and operating conditionsSustainable Energy & Fuels
-
S. Freakley, J. Ruiz-Esquius, David Morgan (2017)
The X‐ray photoelectron spectra of Ir, IrO2 and IrCl3 revisitedSurface and Interface Analysis, 49
-
B. Łosiewicz, R. Jurczakowski, A. Lasia (2017)
Kinetics of hydrogen underpotential deposition at iridium in sulfuric and perchloric acidsElectrochimica Acta, 225
-
Hyung‐Suk Oh, Hong Nong, T. Reier, A. Bergmann, Manuel Gliech, Jorge Araújo, E. Willinger, R. Schlögl, D. Teschner, P. Strasser (2016)
Electrochemical Catalyst-Support Effects and Their Stabilizing Role for IrOx Nanoparticle Catalysts during the Oxygen Evolution Reaction.Journal of the American Chemical Society, 138 38
-
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. Tan, M. Pumera (2017)
Composition-Graded MoWSx Hybrids with Tailored Catalytic Activity by Bipolar Electrochemistry.ACS applied materials & interfaces, 9 48
-
B. Parkinson (2016)
Advantages of Solar Hydrogen Compared to Direct Carbon Dioxide Reduction for Solar Fuel ProductionACS energy letters, 1
-
R. Sun, Chengqi Li, Jinbao Zhang, Fei Li, Liang Ma, Yangguang Tan, Qinglian Wang, Baohong Zhang (2017)
Differential expression of microRNAs during fiber development between fuzzless-lintless mutant and its wild-type allotetraploid cottonScientific Reports, 7
-
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
-
S. Cherevko, S. Cherevko, S. Geiger, O. Kasian, A. Mingers, K. Mayrhofer, K. Mayrhofer, K. Mayrhofer (2016)
Oxygen evolution activity and stability of iridium in acidic media. Part 1. – Metallic iridiumJournal of Electroanalytical Chemistry, 773
-
M. Blasco-Ahicart, Joaquín Soriano-López, J. Carbó, J. Poblet, J. Galán‐Mascarós (2018)
Polyoxometalate electrocatalysts based on earth-abundant metals for efficient water oxidation in acidic media.Nature chemistry, 10 1
-
A. Shpak, A. Korduban, L. Kulikov, T. Kryshchuk, N. Konig, V. Kandyba (2010)
XPS studies of the surface of nanocrystalline tungsten disulfideJournal of Electron Spectroscopy and Related Phenomena, 181
-
Jiajian Gao, Xiang Huang, Weizheng Cai, Qilun Wang, Chunmiao Jia, B. Liu (2020)
Rational Design of Iridium-Tungsten Composite with Iridium-Rich Surface for Acidic Water Oxidation.ACS applied materials & interfaces
-
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
-
Songa Choi, Jongsik Park, Mrinal Kabiraz, Youngmin Hong, Taehyun Kwon, Taekyung Kim, Aram Oh, H. Baik, Minseop Lee, Seung‐Min Paek, Sang‐Il Choi, Kwangyeol Lee (2020)
Electrocatalysts: Pt Dopant: Controlling the Ir Oxidation States toward Efficient and Durable Oxygen Evolution Reaction in Acidic Media (Adv. Funct. Mater. 38/2020)Advanced Functional Materials, 30
-
L. Faria, J. Boodts, S. Trasatti (1996)
Electrocatalytic properties of ternary oxide mixtures of composition Ru0.3Ti(0.7−x)CexO2: oxygen evolution from acidic solutionJournal of Applied Electrochemistry, 26
-
F. Lv, Jianrui Feng, Kai Wang, Zhipeng Dou, Weiyu Zhang, Jin-Yuan Zhou, Chao Yang, Mingchuan Luo, Yong Yang, Yingjie Li, P. Gao, Shaojun Guo (2018)
Iridium–Tungsten Alloy Nanodendrites as pH-Universal Water-Splitting ElectrocatalystsACS Central Science, 4
-
S. Kumari, B. Ajayi, B. Kumar, J. Jasinski, M. Sunkara, J. Spurgeon (2017)
A low-noble-metal W1−xIrxO3−δ water oxidation electrocatalyst for acidic media via rapid plasma synthesisEnergy and Environmental Science, 10
-
A. Pedersen, María Escudero‐Escribano, B. Sebők, A. Bodin, E. Paoli, R. Frydendal, D. Friebel, I. Stephens, J. Rossmeisl, I. Chorkendorff, A. Nilsson (2017)
Operando XAS Study of the Surface Oxidation State on a Monolayer IrOx on RuOx and Ru Oxide Based Nanoparticles for Oxygen Evolution in Acidic Media.The journal of physical chemistry. B, 122 2
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- Wiley
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- © 2021 Wiley‐VCH GmbH
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- 2366-7486
- DOI
- 10.1002/adsu.202000284
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Abstract
Iridium‐based oxides, currently the state‐of‐the‐art oxygen evolution reaction (OER) electrocatalysts in acidic electrolytes, are cost‐intensive materials which undergo significant corrosion under long‐term OER operation. Thus, numerous researchers have devoted their efforts to mitigate iridium corrosion by decoration with corrosion‐resistant metal oxides and/or supports to maximize OER catalyst durability whilst retaining high activity. Herein a one‐step, facile electrochemical route to obtain improved IrOx thin film OER stability in acid by decorating with amorphous tungsten sulphide (WS3−x) upon electrochemical decomposition of a [WS4]2− aqueous precursor is proposed. The rationale behind applying such WS3−x decoration stems from the generation of a tungsten oxide phase, a well‐known corrosion‐resistant photoactive OER catalyst. The study demonstrates the viability of the proposed WS3−x decoration, allowing the tailoring of experimental parameters responsible for WS3−x nanoparticle size and surface coverage. OER stability tests coupled by ex situ SEM and XPS corroborate the beneficial effect of WS3−x decoration, yielding improved OER specific activity metrics along with minimized Ir surface roughening, a characteristic of electrodissolution. Iridium decoration with electrodeposited, corrosion‐resistant oxides is consequently shown to be a promising route to maximize OER stabilities.
Journal
Advanced Sustainable Systems – Wiley
Published: Nov 1, 2021
Keywords: water electrolysis; electrocatalysis; oxygen evolution reaction; iridium; stability; electrochemical deposition; transition metal oxide