On the Operando Structure of Ruthenium Oxides during the Oxygen Evolution Reaction in Acidic Media

In the search for rational design strategies for oxygen evolution reaction (OER) catalysts, linking the catalyst structure to activity and stability is key. However, highly active catalysts such as IrOx and RuOx undergo structural changes under OER conditions, and hence, structure–activity–stability relationships need to take into account the operando structure of the catalyst. Under the highly anodic conditions of the oxygen evolution reaction (OER), electrocatalysts are often converted into an active form. Here, we studied this activation for amorphous and crystalline ruthenium oxide using X-ray absorption spectroscopy (XAS) and electrochemical scanning electron microscopy (EC-SEM). We tracked the evolution of surface oxygen species in ruthenium oxides while in parallel mapping the oxidation state of the Ru atoms to draw a complete picture of the oxidation events that lead to the OER active structure. Our data show that a large fraction of the OH groups in the oxide are deprotonated under OER conditions, leading to a highly oxidized active material. The oxidation is centered not only on the Ru atoms but also on the oxygen lattice. This oxygen lattice activation is particularly strong for amorphous RuOx. We propose that this property is key for the high activity and low stability observed for amorphous ruthenium oxide.

[1]  J. Velasco‐Vélez,et al.  Operando Structure–Activity–Stability Relationship of Iridium Oxides during the Oxygen Evolution Reaction , 2022, ACS Catalysis.

[2]  R. Schlögl,et al.  Surface Electron-Hole Rich Species Active in the Electrocatalytic Water Oxidation , 2021, Journal of the American Chemical Society.

[3]  J. Rossmeisl,et al.  Lifting the discrepancy between experimental results and the theoretical predictions for the catalytic activity of RuO2(110) towards oxygen evolution reaction. , 2021, Physical chemistry chemical physics : PCCP.

[4]  A. Bhaumik,et al.  Microporous nickel phosphonate derived heteroatom doped nickel oxide and nickel phosphide: Efficient electrocatalysts for oxygen evolution reaction , 2021 .

[5]  K. Dastafkan,et al.  Metal–Organic Framework-Derived Bimetallic NiFe Selenide Electrocatalysts with Multiple Phases for Efficient Oxygen Evolution Reaction , 2021, ACS Sustainable Chemistry & Engineering.

[6]  M. Hävecker,et al.  A comparative study of electrochemical cells for in situ x-ray spectroscopies in the soft and tender x-ray range , 2020 .

[7]  R. Schlögl,et al.  Key role of chemistry versus bias in electrocatalytic oxygen evolution , 2020, Nature.

[8]  S. Baranton,et al.  Green Synthesis and Modification of RuO2 Materials for the Oxygen Evolution Reaction , 2020, Frontiers in Energy Research.

[9]  Y. Bando,et al.  Multiscale structural optimization: Highly efficient hollow iron-doped metal sulfide heterostructures as bifunctional electrocatalysts for water splitting , 2020 .

[10]  R. Schlögl,et al.  Graphene-Capped Liquid Thin Films for Electrochemical Operando X-ray Spectroscopy and Scanning Electron Microscopy , 2020, ACS applied materials & interfaces.

[11]  Nugraha,et al.  Self-Assembly of Two-Dimensional Bimetallic Nickel–Cobalt Phosphate Nanoplates into One-Dimensional Porous Chainlike Architecture for Efficient Oxygen Evolution Reaction , 2020 .

[12]  Q. Wei,et al.  MOF-Derived Sulfide-Based Electrocatalyst and Scaffold for Boosted Hydrogen Production. , 2020, ACS applied materials & interfaces.

[13]  Jonathan Hwang,et al.  Operando identification of site-dependent water oxidation activity on ruthenium dioxide single-crystal surfaces , 2020, Nature Catalysis.

[14]  Zhichuan J. Xu,et al.  A review on fundamentals for designing oxygen evolution electrocatalysts. , 2020, Chemical Society reviews.

[15]  Nugraha,et al.  Tailorable nanoarchitecturing of bimetallic nickel–cobalt hydrogen phosphate via the self-weaving of nanotubes for efficient oxygen evolution , 2020 .

[16]  S. Garg,et al.  Advances and challenges in electrochemical CO2reduction processes: an engineering and design perspective looking beyond new catalyst materials , 2020, Journal of Materials Chemistry A.

[17]  V. Aravindan,et al.  Developments and Perspectives in 3d Transition‐Metal‐Based Electrocatalysts for Neutral and Near‐Neutral Water Electrolysis , 2019, Advanced Energy Materials.

[18]  B. Liu,et al.  Utilizing solar energy to improve the oxygen evolution reaction kinetics in zinc–air battery , 2019, Nature Communications.

[19]  B. Yuliarto,et al.  Holey Assembly of Two-Dimensional Iron-Doped Nickel-Cobalt Layered Double Hydroxide Nanosheets for Energy Conversion Application. , 2019, ChemSusChem.

[20]  Adam C. Nielander,et al.  A rigorous electrochemical ammonia synthesis protocol with quantitative isotope measurements , 2019, Nature.

[21]  R. Schlögl,et al.  The Oxidation of Platinum under Wet Conditions Observed by Electrochemical X-ray Photoelectron Spectroscopy , 2019, Journal of the American Chemical Society.

[22]  R. Schlögl,et al.  In Situ X-ray Spectroscopy of the Electrochemical Development of Iridium Nanoparticles in Confined Electrolyte , 2019, The Journal of Physical Chemistry C.

[23]  T. Schmidt,et al.  Oxygen Evolution Reaction—The Enigma in Water Electrolysis , 2018, ACS Catalysis.

[24]  Simon Geiger,et al.  The Common Intermediates of Oxygen Evolution and Dissolution Reactions during Water Electrolysis on Iridium , 2018, Angewandte Chemie.

[25]  P. Kurzweil,et al.  The Redox Chemistry of Ruthenium Dioxide: A Cyclic Voltammetry Study—Review and Revision , 2018 .

[26]  Ping Liu,et al.  Reaction mechanism for oxygen evolution on RuO2, IrO2, and RuO2@IrO2 core-shell nanocatalysts , 2017, Journal of Electroanalytical Chemistry.

[27]  Yang Shao-Horn,et al.  Orientation-Dependent Oxygen Evolution on RuO2 without Lattice Exchange , 2017 .

[28]  Quan Quan,et al.  Electrocatalysis for the oxygen evolution reaction: recent development and future perspectives. , 2017, Chemical Society reviews.

[29]  R. Schlögl,et al.  In situ observation of reactive oxygen species forming on oxygen-evolving iridium surfaces† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c6sc04622c Click here for additional data file. , 2016, Chemical science.

[30]  A. Ludwig,et al.  On the Origin of the Improved Ruthenium Stability in RuO2–IrO2 Mixed Oxides , 2016 .

[31]  P. Strasser,et al.  An efficient bifunctional two-component catalyst for oxygen reduction and oxygen evolution in reversible fuel cells, electrolyzers and rechargeable air electrodes , 2016 .

[32]  Pamela A. Silver,et al.  Water splitting–biosynthetic system with CO2 reduction efficiencies exceeding photosynthesis , 2016, Science.

[33]  Alfred Ludwig,et al.  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 stability , 2016 .

[34]  D. Morgan Resolving ruthenium: XPS studies of common ruthenium materials , 2015 .

[35]  M. Gaberšček,et al.  New Insights into Corrosion of Ruthenium and Ruthenium Oxide Nanoparticles in Acidic Media , 2015 .

[36]  A. D. Corso Pseudopotentials periodic table: From H to Pu , 2014 .

[37]  Emiliana Fabbri,et al.  Developments and perspectives of oxide-based catalysts for the oxygen evolution reaction , 2014 .

[38]  I. Chorkendorff,et al.  Oxygen evolution on well-characterized mass-selected Ru and RuO2 nanoparticles† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c4sc02685c Click here for additional data file. , 2014, Chemical science.

[39]  Aleksandar R. Zeradjanin,et al.  Dissolution of Noble Metals during Oxygen Evolution in Acidic Media , 2014 .

[40]  A. Vertova,et al.  Observing the oxidation state turnover in heterogeneous iridium-based water oxidation catalysts , 2014 .

[41]  M. L. Ng,et al.  In situ observation of surface species on iridium oxide nanoparticles during the oxygen evolution reaction. , 2014, Angewandte Chemie.

[42]  Nemanja Danilovic,et al.  Activity-Stability Trends for the Oxygen Evolution Reaction on Monometallic Oxides in Acidic Environments. , 2014, The journal of physical chemistry letters.

[43]  Y. Shao-horn,et al.  Orientation-Dependent Oxygen Evolution Activities of Rutile IrO2 and RuO2. , 2014, The journal of physical chemistry letters.

[44]  Peter Strasser,et al.  Electrocatalytic Oxygen Evolution Reaction (OER) on Ru, Ir, and Pt Catalysts: A Comparative Study of Nanoparticles and Bulk Materials , 2012 .

[45]  H. Over Surface chemistry of ruthenium dioxide in heterogeneous catalysis and electrocatalysis: from fundamental to applied research. , 2012, Chemical reviews.

[46]  John Kitchin,et al.  Universality in Oxygen Evolution Electrocatalysis on Oxide Surfaces , 2011 .

[47]  Stefano de Gironcoli,et al.  QUANTUM ESPRESSO: a modular and open-source software project for quantum simulations of materials , 2009, Journal of physics. Condensed matter : an Institute of Physics journal.

[48]  T. Sham,et al.  Immobilization of RuO2 on Carbon Nanotube: An X-ray Absorption Near-Edge Structure Study , 2009 .

[49]  W. Sloof,et al.  Unraveling the oxidation of Ru using XPS , 2008 .

[50]  C. H. Chen,et al.  Comparison of electronic structures of RuO2 and IrO2 nanorods investigated by x-ray absorption and scanning photoelectron microscopy , 2007 .

[51]  R. Kötz,et al.  An X-ray photoelectron spectroscopy study of hydrous ruthenium oxide powders with various water contents for supercapacitors , 2006 .

[52]  I. Stefan,et al.  In Situ Ru LII and LIII Edge X-ray Absorption Near Edge Structure of Electrodeposited Ruthenium Dioxide Films , 2002 .

[53]  F. Mauri,et al.  X-ray absorption near-edge structure calculations with the pseudopotentials: Application to the K edge in diamond and α-quartz , 2002, cond-mat/0207733.

[54]  W. Cullen,et al.  Electrochemical and X-ray scattering study of well defined RuO2 single crystal surfaces , 2002 .

[55]  Astronomy,et al.  THERMAL CONTRACTION AND DISORDERING OF THE AL(110) SURFACE , 1999, cond-mat/9903147.

[56]  Burke,et al.  Generalized Gradient Approximation Made Simple. , 1996, Physical review letters.

[57]  M. Wohlfahrt‐Mehrens,et al.  Oxygen Evolution on Ru and RuO2 Electrodes Studied Using Isotope Labelling and On-Line Mass Spectrometry. , 1988 .

[58]  M. Wohlfahrt‐Mehrens,et al.  Oxygen evolution on Ru and RuO2 electrodes studied using isotope labelling and on-line mass spectrometry , 1987 .

[59]  R. Kötz,et al.  Stabilization of RuO2 by IrO2 for anodic oxygen evolution in acid media , 1986 .

[60]  F. Lévy,et al.  Optical and Electrical Properties of of Ruthenium-Doped TiO2 , 1985, May 1.

[61]  W. O'grady,et al.  Effect of Crystallographic Orientation of Single‐Crystal RuO2 Electrodes on the Hydrogen Adsorption Reactions , 1984 .

[62]  R. Kötz,et al.  In-situ identification of RuO4 as the corrosion product during oxygen evolution on ruthenium in acid media , 1984 .

[63]  M. Vázquez,et al.  Passivation of ruthenium in hydrochloric acid solution , 1966 .

[64]  Robert Schlögl,et al.  Electrocatalytic Oxygen Evolution Reaction in Acidic Environments – Reaction Mechanisms and Catalysts , 2017 .

[65]  I. Chorkendorff,et al.  Oxygen evolution on well-characterized mass-selected Ru and RuO2 nanoparticles , 2014, Chemical science.

[66]  R. Kötz,et al.  Anodic Iridium Oxide Films XPS‐Studies of Oxidation State Changes and , 1984 .