DOE PAGES title logo U.S. Department of Energy
Office of Scientific and Technical Information
  1. Enhancing Acidic Oxygen Evolution Activity by Supporting Iridium Electrocatalysts on Tantalum Carbide

    For a high-performance proton exchange membrane water electrolyzer (PEMWE), acidic oxygen evolution reaction (OER) electrocatalysts require highly dispersed iridium oxide (IrOx) nanoparticles. Although carbon-based materials have been explored as promising supports for IrOx nanoparticles, their limited stability under harsh oxidative and acidic PEMWE conditions remains a significant challenge. Here, in this study, we report the synthesis and in situ characterization of active and durable IrOx electrocatalysts supported on electrochemically stable and electrically conducting tantalum carbide (TaC). When applied in a PEMWE, the IrOx/TaC electrocatalyst achieves a cell voltage of 1.71 V at 1.0 A cm–2, outperforming the commercial IrO2 catalystmore » (1.82 V at 1.0 A cm–2). Furthermore, the IrOx/TaC catalyst maintains a stable operation for 200 h at 0.5 A cm–2 with a low degradation rate of 36 μV h–1. Density functional theory calculations further confirm that Ir–O–Ta bond formation at the IrOx/TaC interface reduces the overpotential of the OER compared to IrO2. This study underscores the pivotal role of supporting IrOx over stable and conducting metal carbides, providing guidance for the design of advanced acidic OER catalysts.« less
  2. A versatile and practical synthesis of oxygen evolution catalysts

    State-of-the-art OER (oxygen evolution reaction) catalyst syntheses require the use of expensive metals (i.e. Ir) with complex and time-consuming synthetic routes, difficulty in control, and impractical yields. Although some reported catalysts show improved performance (i.e. activity, stability, lowering Ir content with Ru), their synthesis is costly and not viable for scale-up. Here we demonstrate a practical, reliable, and scalable one-pot synthesis method for OER catalysts based on borohydride reduction to quickly yield >100 mg of Ir, Ru, and IrRu nanoparticles (1.6 ± 0.2 nm) with outstanding batch-to-batch consistency. Both mono- and bi-metallic compositions exhibit a metal-core/metal-oxide-shell nanoparticle structure. We furthermore » demonstrate the versatility of this method by incorporating earth-abundant yttrium, resulting in a catalyst with improved precious metal utilization for OER. This method serves as a robust platform for generating ultrasmall (<2 nm) multi-metal particles useful for electrocatalysis research.« less
  3. Oxygen Atom Transfer Reactions of Colloidal Metal Oxide Nanoparticles

    Redox transformations at metal oxide (MOx)/solution interfaces are broadly important, and oxygen atom transfer (OAT) is one of the simplest and most fundamental examples of such reactivity. OAT is a two-electron transfer process, well-known in gas/solid reactions and catalysis. However, OAT is rarely directly observed at oxide/water interfaces, whose redox reactions are typically proposed to occur in one-electron steps. Reported here are stoichiometric OAT reactions of organic molecules with aqueous colloidal titanium dioxide and iridium oxide nanoparticles (TiO2 and IrOx NPs). Me2SO (DMSO) oxidizes reduced TiO2 NPs with the formation of Me2S, and IrOx NPs transfer O atoms to amore » water-soluble phosphine and a thioether. The reaction stoichiometries were established and the chemical mechanisms were probed using typical solution spectroscopic techniques, exploiting the high surface areas and transparency of the colloids. Furthermore, these OAT reactions, including a catalytic example, utilize the ability of the individual NPs to accumulate many electrons and/or holes. Observing OAT reactions of two different materials, in opposite directions, is a step toward harnessing oxide nanoparticles for valuable multi-electron and multi-hole transformations.« less
  4. Quantification of Reactive Oxygen Species Produced from Electrocatalytic Materials

    Oxygen electrochemistry goes beyond O2, as the formation of reactive oxygen species (ROS) such as H2O2 and O3 during water oxidation is key in the destruction of persistent pollutants in water remediation technologies as well as in the degradation of fuel cell and electrolyzer components. In this study, we developed an in situ method utilizing the rotating ring-disk electrode technique to quantify the formation of O2, O3, and H2O2 species across a broad pH range (1–8.3). Oxygen selectivity trends over Pt, IrO2, and PbO2 surfaces reveal that even O2 evolution catalysts may produce small yet measurable amounts of ROS, furthermore » modulated by pH and electrode potential. In conclusion, these findings emphasize the need to probe the selectivity of oxygen electrochemistry for a more complete picture of advanced materials for electrochemical technologies.« less
  5. Nanochannel electrodes facilitating interfacial transport for PEM water electrolysis

    Proton-exchange membrane water electrolyzers (PEMWEs) are a promising technology for green hydrogen production; however, interfacial transport behaviors are poorly understood, hindering device performance and longevity. Here, we first utilized finite-gap electrolyzer to demonstrate the possibility of proton transfer through water in PEMWEs. The measured high-frequency resistances (HFRs) exhibit a linear trend with increasing gap distance, where extrapolation shows a lower value compared with HFRs in regular zero-gap electrolyzers, indicating that ohmic resistance could be further reduced. We introduce nanochannels to facilitate mass transport, as evidenced by both liquid-fed and vapor-fed electrolysis. Nanochannel electrodes achieve a voltage reduction of 190 mVmore » at 9 A·cm–2 compared with the Ir-PTEs without nanochannels. Furthermore, nanochannel electrodes show negligible degradation through 100,000 accelerated-stress tests and over 2,000 h of operation at 1.8 A·cm–2 with a decay rate of 11.66 μV·h–1. These results provide new insights into localized transport dynamics for PEMWEs and highlight the significance of interfacial engineering for electrochemical devices.« less
  6. Highly stable preferential carbon monoxide oxidation by dinuclear heterogeneous catalysts

    Atomically dispersed catalysts have been shown highly active for preferential oxidation of carbon monoxide in the presence of excess hydrogen (PROX). However, their stability has been less than ideal. We show here that the introduction of a structural component to minimize diffusion of the active metal center can greatly improve the stability without compromising the activity. Using an Ir dinuclear heterogeneous catalyst (DHC) as a study platform, we identify two types of oxygen species, interfacial and bridge, that work in concert to enable both activity and stability. In conclusion, the work sheds important light on the synergistic effect between themore » active metal center and the supporting substrate and may find broad applications for the use of atomically dispersed catalysts.« less
  7. Standard atomic weights of the elements 2021 (IUPAC Technical Report)

    Following the reviews of atomic-weight determinations and other cognate data in 2015, 2017, 2019 and 2021, the IUPAC (International Union of Pure and Applied Chemistry) Commission on Isotopic Abundances and Atomic Weights (CIAAW) reports changes of standard atomic weights. The symbol A r°(E) was selected for standard atomic weight of an element to distinguish it from the atomic weight of an element E in a specific substance P, designated A r(E, P). The CIAAW has changed the values of the standard atomic weights of five elements based on recent determinations of terrestrial isotopic abundances. The standard atomic weight of argonmore » and lead have changed to an interval to reflect that the natural variation in isotopic composition exceeds the measurement uncertainty of A r(Ar) and A r(Pb) in a specific substance. The standard atomic weights and/or the uncertainties of fourteen elements have been changed based on the Atomic Mass Evaluations 2016 and 2020 accomplished under the auspices of the International Union of Pure and Applied Physics (IUPAP). A r° of Ho, Tb, Tm and Y were changed in 2017 and again updated in 2021.« less
  8. Chapter One - Selectivity in the activation of C–H bonds by rhodium and iridium complexes

    Trispyrazolylborate complexes of rhodium and iridium have been extensively investigated over the past 3 decades with special attention to their ability to activate C–H bonds. The rhodium complexes of tris-(3,5-dimethylpyrazolyl)borate have been the subject of numerous thermodynamic investigations that provide information about rhodium-metal carbon bond strengths. This insight arises as a result of the reversibility of C–H activation with rhodium. In the case of iridium, C–H bond activation reactions are also widespread, and some of these also show reversibility. Access to some key trispyrazolylborate iridium(I) and iridium(III) starting materials has given way to a multitude of studies of reactions withmore » small molecules in which C–H bonds are made and broken reversibly. The stability of Fischer carbenes plays a role in the observed products. Here, the reactivity of trispyrazolylborate complexes of rhodium and iridium compounds over the past decade (since 2010) are summarized here. Related reactions of X–H bonds with these trispyrazolylborate compounds are also included for completeness (X = O, N, S, B, Si).« less
  9. P–V–T Equation of State of Iridium Up to 80 GPa and 3100 K

    In the present study, the high-pressure high-temperature equation of the state of iridium has been determined through a combination of in situ synchrotron X-ray diffraction experiments using laser-heating diamond-anvil cells (up to 48 GPa and 3100 K) and density-functional theory calculations (up to 80 GPa and 3000 K). The melting temperature of iridium at 40 GPa was also determined experimentally as being 4260 (200) K. The results obtained with the two different methods are fully consistent and agree with previous thermal expansion studies performed at ambient pressure. The resulting thermal equation of state can be described using a third-order Birch–Murnaghanmore » formalism with a Berman thermal-expansion model. The present equation of the state of iridium can be used as a reliable primary pressure standard for static experiments up to 80 GPa and 3100 K. A comparison with gold, copper, platinum, niobium, rhenium, tantalum, and osmium is also presented. On top of that, the radial-distribution function of liquid iridium has been determined from experiments and calculations.« less
...

Search for:
All Records
Subject
iridium

Refine by:
Article Type
Availability
Journal
Creator / Author
Publication Date
Research Organization