Your search keyword '"Serhiy, Cherevko"' showing total 10 results

1. Oxygen Evolution Electrocatalysis in Acids: Atomic Tuning of the Stability Number for Submonolayer IrOx on Conductive Oxides from Molecular Precursors

Author

Raina A. Krivina, Matej Zlatar, T. Nathan Stovall, Grace A. Lindquist, Daniel Escalera-López, Amanda K. Cook, James E. Hutchison, Serhiy Cherevko, and Shannon W. Boettcher

Subjects

General Chemistry, Catalysis

Published

2022

2. CrOx-mediated performance enhancement of Ni/NiO-Mg:SrTiO3in photocatalytic water splitting

Author

Caroline Lievens, Guido Mul, Bastian Mei, Peter A. Crozier, Kai Han, Diane M. Haiber, Julius Knöppel, Serhiy Cherevko, Photocatalytic Synthesis, UT-I-ITC-4DEarth, Faculty of Geo-Information Science and Earth Observation, Department of Earth Systems Analysis, and MESA+ Institute

Subjects

Materials science, Dopant, Doping, Non-blocking I/O, SrTiO, UT-Hybrid-D, Nanoparticle, General Chemistry, Co-catalyst, Catalysis, Contact angle, ITC-HYBRID, Chemical engineering, In situ ICP-MS, ITC-ISI-JOURNAL-ARTICLE, ddc:540, Photocatalysis, Water splitting, Photocatalytic water splitting, Stability

Abstract

By photodeposition of CrOx on SrTiO3-based semiconductors doped with aliovalent Mg(II) and functionalized with Ni/NiOx catalytic nanoparticles (economically significantly more viable than commonly used Rh catalysts), an increase in apparent quantum yield (AQYs) from ∼10 to 26% in overall water splitting was obtained. More importantly, deposition of CrOx also significantly enhances the stability of Ni/NiO nanoparticles in the production of hydrogen, allowing sustained operation, even in intermittent cycles of illumination. In situ elemental analysis of the water constituents during or after photocatalysis by inductively coupled plasma mass spectrometry/optical emission spectrometry shows that after CrOx deposition, dissolution of Ni ions from Ni/NiOx-Mg:SrTiO3 is significantly suppressed, in agreement with the stabilizing effect observed, when both Mg dopant and CrOx are present. State-of-the-art electron microscopy and energy-dispersive X-ray spectroscopy (EDX) and electron energy-loss spectroscopy (EELS) analyses demonstrate that upon preparation, CrOx is photodeposited in the vicinity of several, but not all, Ni/NiOx particles. This implies the formation of a Ni-Cr mixed metal oxide, which is highly effective in water reduction. Inhomogeneities in the interfacial contact, evident from differences in contact angles between Ni/NiOx particles and the Mg:SrTiO3 semiconductor, likely affect the probability of reduction of Cr(VI) species during synthesis by photodeposition, explaining the observed inhomogeneity in the spatial CrOx distribution. Furthermore, by comparison with undoped SrTiO3, Mg-doping appears essential to provide such favorable interfacial contact and to establish the beneficial effect of CrOx. This study suggests that the performance of semiconductors can be significantly improved if inhomogeneities in interfacial contact between semiconductors and highly effective catalytic nanoparticles can be resolved by (surface) doping and improved synthesis protocols.

Published

2021

3. Sacrificial Cu Layer Mediated the Formation of an Active and Stable Supported Iridium Oxygen Evolution Reaction Electrocatalyst

Author

Armin Hrnjić, Francisco Ruiz-Zepeda, Martin Šala, Serhiy Cherevko, Nejc Hodnik, Daniel Escalera-López, Marjan Bele, Primož Jovanovič, and Anja Loncar

Subjects

Materials science, chemistry.chemical_element, Nanoparticle, 02 engineering and technology, 010402 general chemistry, Electrochemistry, Electrocatalyst, 7. Clean energy, 01 natural sciences, Catalysis, S-number, identical location transmission electron microscopy (IL-TEM), iridium nanoparticles, Iridium, oxygen evolution reaction (OER), titanium oxynitride (TiON) support, Oxygen evolution, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemical engineering, chemistry, ddc:540, Inductively coupled plasma, 0210 nano-technology, Titanium, Research Article

Abstract

The production of hydrogen via a proton-exchange membrane water electrolyzer (PEM-WE) is directly dependent on the rational design of electrocatalysts for the anodic oxygen evolution reaction (OER), which is the bottleneck of the process. Here, we present a smart design strategy for enhancing Ir utilization and stabilization. We showcase it on a catalyst, where Ir nanoparticles are efficiently anchored on a conductive support titanium oxynitride (TiON x ) dispersed over carbon-based Ketjen Black and covered by a thin layer of copper (Ir/CuTiON x /C), which gets removed in the preconditioning step. Electrochemical OER activity, stability, and structural changes were compared to the Ir-based catalyst, where Ir nanoparticles without Cu are deposited on the same support (Ir/TiON x /C). To study the effect of the sacrificial less-noble metal layer on the catalytic performance of the synthesized material, characterization methods, namely X-ray powder diffraction, X-ray photoemission spectroscopy, and identical location transmission electron microscopy were employed and complemented with scanning flow cell coupled to an inductively coupled plasma mass spectrometer, which allowed studying the online dissolution during the catalytic reaction. Utilization of these advanced methods revealed that the sacrificial Cu layer positively affects both Ir OER mass activity and its durability, which was assessed via S-number, a recently reported stability metric. Improved activity of Cu analogue was ascribed to the higher surface area of smaller Ir nanoparticles, which are better stabilized through a strong metal-support interaction (SMSI) effect.

Published

2021

4. Interplay Among Dealloying, Ostwald Ripening, and Coalescence in PtXNi100–X Bimetallic Alloys under Fuel-Cell-Related Conditions

Author

Daniel J. S. Sandbeck, Heinz Amenitsch, Ivan Khalakhan, Serhiy Cherevko, Marco Bogar, Yurii Yakovlev, Iva Matolínová, Bogar, Marco, Yakovlev, Yurii, John Seale Sandbeck, Daniel, Cherevko, Serhiy, Matolínová, Iva, Amenitsch, Heinz, and Khalakhan, Ivan

Subjects

Ostwald ripening, particle coalescence, Materials science, General Chemistry, in situ grazing-incidence small-angle X-ray scattering, Catalysis, fuel cell, symbols.namesake, Chemical engineering, symbols, Fuel cells, Coalescence (chemistry), bimetallic catalyst dealloying, Bimetallic strip, degradation

Abstract

Platinum-based bimetallic alloys have been largely investigated during the last few years as a valid alternative to bare Pt cathode catalysts for proton-exchange membrane fuel cells (PEMFCs) to improve their cost-efficiency. Nonetheless, Pt bimetallic alloys are characterized by a reduced stability, which is poorly understood at a fundamental level. It is thus essential to describe the entire chain of interconnected degradation mechanisms to formulate a comprehensive model of catalyst degradation that will help interpret bimetallic alloy behavior in real complex fuel cell systems. By combining in situ inductively coupled plasma mass spectroscopy, in situ grazing-incidence small-angle X-ray scattering, and ex situ scanning electron microscopy, we have studied the morphological evolution of PtXNi100–X model catalysts with different Ni contents (ranging from 0 to 75%) undergoing potentiodynamic cycling to two different upper potentials mimicking the different operational conditions of a PEMFC: 1.0 and 1.3 VRHE. Data analysis allowed us to develop a methodology to distinguish the influence of Ni dissolution, particle coalescence, and Ostwald ripening on particle size distribution and interparticle distance and to realize time-dependent interplay maps to highlight the timeframe in which the aforementioned phenomena are prevailing or coexisting. Results show that Ni dissolution is the only phenomenon inducing morphological evolution when the lower upper potential is chosen. On the contrary, at 1.3 VRHE, Ni dissolution is rapidly overcome by particle coalescence at first and by Ostwald ripening in the later stages of the investigated time range. The onset of every phenomenon was found to occur earlier in time for larger values of Ni concentrations.

Published

2021

5. Increased Ir–Ir Interaction in Iridium Oxide during the Oxygen Evolution Reaction at High Potentials Probed by Operando Spectroscopy

Author

Philipp Röse, Vitaly Alexandrov, Janis Geppert, Serhiy Cherevko, Alexandra Zagalskaya, Ulrike Krewer, Steffen Czioska, Erisa Saraçi, Daniel Escalera-López, Jan-Dierk Grunwaldt, and Alexey Boubnov

Subjects

Technology, spectroscopy, Materials science, Absorption spectroscopy, XAS, splitting, water, dissolution, chemistry.chemical_element, reaction, Catalysis, Operando spectroscopy, Oxidation state, evolution, Iridium, X-ray absorption spectroscopy, Electrolysis of water, situ, Oxygen evolution, excitation, General Chemistry, in, iridium, stability, pyrolysis, modulation, spray, chemistry, flame, ddc:540, Physical chemistry, oxide, ddc:600, oxygen

Abstract

The structure of IrO$_{2}$ during the oxygen evolution reaction (OER) was studied by operando X-ray absorption spectroscopy (XAS) at the Ir L$_{3}$-edge to gain insight into the processes that occur during the electrocatalytic reaction at the anode during water electrolysis. For this purpose, calcined and uncalcined IrO$_{2}$ nanoparticles were tested in an operando spectroelectrochemical cell. In situ XAS under different applied potentials uncovered strong structural changes when changing the potential. Modulation excitation spectroscopy combined with XAS enhanced the information on the dynamic changes significantly. Principal component analysis (PCA) of the resulting spectra as well as FEFF9 calculations uncovered that both the Ir L$_{3}$-edge energy and the white line intensity changed due to the formation of oxygen vacancies and lower oxidation state of iridium at higher potentials, respectively. The deconvoluted spectra and their components lead to two different OER modes. It was observed that at higher OER potentials, the well-known OER mechanisms need to be modified, which is also associated with the stabilization of the catalyst, as confirmed by in situ inductively coupled plasma mass spectrometry (ICP-MS). At these elevated OER potentials above 1.5 V, stronger Ir���Ir interactions were observed. They were more dominant in the calcined IrO$_{2}$ samples than in the uncalcined ones. The stronger Ir���Ir interaction upon vacancy formation is also supported by theoretical studies. We propose that this may be a crucial factor in the increased dissolution stability of the IrO$_{2}$ catalyst after calcination. The results presented here provide additional insights into the OER in acid media and demonstrate a powerful technique for quantifying the differences in mechanisms on different OER electrocatalysts. Furthermore, insights into the OER at a fundamental level are provided, which will contribute to further understanding of the reaction mechanisms in water electrolysis.

Published

2021

6. Particle Size Effect on Platinum Dissolution: Considerations for Accelerated Stability Testing of Fuel Cell Catalysts

Author

Jakob Kibsgaard, Florian Speck, Jakob Ejler Sørensen, Ib Chorkendorff, Niklas Mørch Secher, Daniel J. S. Sandbeck, and Serhiy Cherevko

Subjects

chemistry.chemical_classification, Materials science, 010405 organic chemistry, Proton exchange membrane fuel cell, General Chemistry, Electrolyte, Polymer, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Membrane, Chemical engineering, chemistry, Fuel cells, Degradation (geology), Particle size

Abstract

Polymer electrolyte membrane fuel cells (PEMFCs) are highly attractive for use in electric vehicles. In PEMFCs, small particle sizes of the Pt catalyst are required to increase Pt utilization, whic...

Published

2020

7. CrO

Author

Kai, Han, Diane M, Haiber, Julius, Knöppel, Caroline, Lievens, Serhiy, Cherevko, Peter, Crozier, Guido, Mul, and Bastian, Mei

Subjects

photocatalytic water splitting, co-catalyst, in situ ICP-MS, SrTiO3, stability, Research Article

Abstract

By photodeposition of CrOx on SrTiO3-based semiconductors doped with aliovalent Mg(II) and functionalized with Ni/NiOx catalytic nanoparticles (economically significantly more viable than commonly used Rh catalysts), an increase in apparent quantum yield (AQYs) from ∼10 to 26% in overall water splitting was obtained. More importantly, deposition of CrOx also significantly enhances the stability of Ni/NiO nanoparticles in the production of hydrogen, allowing sustained operation, even in intermittent cycles of illumination. In situ elemental analysis of the water constituents during or after photocatalysis by inductively coupled plasma mass spectrometry/optical emission spectrometry shows that after CrOx deposition, dissolution of Ni ions from Ni/NiOx-Mg:SrTiO3 is significantly suppressed, in agreement with the stabilizing effect observed, when both Mg dopant and CrOx are present. State-of-the-art electron microscopy and energy-dispersive X-ray spectroscopy (EDX) and electron energy-loss spectroscopy (EELS) analyses demonstrate that upon preparation, CrOx is photodeposited in the vicinity of several, but not all, Ni/NiOx particles. This implies the formation of a Ni–Cr mixed metal oxide, which is highly effective in water reduction. Inhomogeneities in the interfacial contact, evident from differences in contact angles between Ni/NiOx particles and the Mg:SrTiO3 semiconductor, likely affect the probability of reduction of Cr(VI) species during synthesis by photodeposition, explaining the observed inhomogeneity in the spatial CrOx distribution. Furthermore, by comparison with undoped SrTiO3, Mg-doping appears essential to provide such favorable interfacial contact and to establish the beneficial effect of CrOx. This study suggests that the performance of semiconductors can be significantly improved if inhomogeneities in interfacial contact between semiconductors and highly effective catalytic nanoparticles can be resolved by (surface) doping and improved synthesis protocols.

Published

2021

8. In Situ Stability Studies of Platinum Nanoparticles Supported on Ruthenium−Titanium Mixed Oxide (RTO) for Fuel Cell Cathodes

Author

Peter Strasser, Karl Johann Jakob Mayrhofer, Stefanie Kühl, Vijay Ramani, Elisabeth Hornberger, Serhiy Cherevko, Jakub Drnec, Henrike Schmies, Daniel J. S. Sandbeck, Guanxiong Wang, and Arno Bergmann

Subjects

Materials science, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Platinum nanoparticles, Electrochemistry, Electrocatalyst, 01 natural sciences, Catalysis, 0104 chemical sciences, Ruthenium, chemistry, Chemical engineering, Mixed oxide, 0210 nano-technology, Dissolution, Titanium

Abstract

Using a variety of in situ techniques, we tracked the structural stability and concomitantly the electrocatalytic oxygen reduction reaction (ORR) of platinum nanoparticles on ruthenium–titanium mixed oxide (RTO) supports during electrochemical accelerated stress tests, mimicking fuel cell operating conditions. High-energy X-ray diffraction (HE-XRD) offered insights in the evolution of the morphology and structure of RTO-supported Pt nanoparticles during potential cycling. The changes of the atomic composition were tracked in situ using scanning flow cell measurements coupled to inductively coupled plasma mass spectrometry (SFC-ICP-MS). We excluded Pt agglomeration, particle growth, dissolution, or detachment as cause for the observed losses in catalytic ORR activity. Instead, we argue that Pt surface poisoning is the most likely cause of the observed catalytic rate decrease. Data suggest that the gradual growth of a thin oxide layer on the Pt nanoparticles due to strong metal–support interaction (SMSI) is...

Published

2018

9. Gold–Palladium Bimetallic Catalyst Stability: Consequences for Hydrogen Peroxide Selectivity

Author

Graham J. Hutchings, Sriram Venkatesan, Christian Liebscher, Karl Johann Jakob Mayrhofer, Simon J. Freakley, Enrico Pizzutilo, Serhiy Cherevko, and Gerhard Dehm

Subjects

Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, Electrocatalyst, 01 natural sciences, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Cyclic voltammetry, 0210 nano-technology, Hydrogen peroxide, Bimetallic strip, Dissolution, Palladium

Abstract

During application, electrocatalysts are exposed to harsh electrochemical conditions, which can induce degradation. This work addresses the degradation of AuPd bimetallic catalysts used for the electrocatalytic production of hydrogen peroxide (H2O2) by the oxygen reduction reaction (ORR). Potential-dependent changes in the AuPd surface composition occur because the two metals have different dissolution onset potentials, resulting in catalyst dealloying. Using a scanning flow cell (SFC) with an inductively coupled plasma mass spectrometer (ICP-MS), simultaneous Pd and/or Au dissolution can be observed. Thereafter, three accelerated degradation protocols (ADPs), simulating different dissolution regimes, are employed to study the catalyst structure degradation on the nanoscale with identical location (IL) TEM. When only Pd or both Au and Pd dissolve, the composition changes rapidly and the surface becomes enriched with Au, as observed by cyclic voltammetry and elemental mapping. Such changes are mirrored by the evolution of electrocatalytic performances toward H2O2 production. Our experimental findings are finally summarized in a dissolution/structure/selectivity mechanism, providing a clear picture of the degradation of bimetallic catalyst used for H2O2 synthesis.

Published

2017

10. Tuning the Electrocatalytic Performance of Ionic Liquid Modified Pt Catalysts for the Oxygen Reduction Reaction via Cationic Chain Engineering

Author

Serhiy Cherevko, Daniel J. S. Sandbeck, Macarena Munoz, Bastian J. M. Etzold, Gui-Rong Zhang, Thomas Wolker, and Karl Johann Jakob Mayrhofer

Subjects

Pt dissolution, 02 engineering and technology, 010402 general chemistry, Electrocatalyst, 01 natural sciences, Catalysis, fuel cell, chemistry.chemical_compound, electrocatalysis, Oxygen reduction reaction, Pt catalyst, Imide, Alkyl, ionic liquid, chemistry.chemical_classification, Chemistry, Active surface area, Cationic polymerization, General Chemistry, 021001 nanoscience & nanotechnology, oxygen reduction, 0104 chemical sciences, Chemical engineering, 13. Climate action, Ionic liquid, ddc:540, 0210 nano-technology, Research Article

Abstract

Modifying Pt catalysts using hydrophobic ionic liquids (ILs) has been demonstrated to be a facile approach for boosting the performance of Pt catalysts for the oxygen reduction reaction (ORR). This work aims to deepen the understanding and initiate a rational molecular tuning of ILs for improved activity and stability. To this end, Pt/C catalysts were modified using a variety of 1-methyl-3-alkylimidazolium bis(trifluoromethanesulfonyl)imide ([CnC1im][NTf2], n = 2–10) ILs with varying alkyl chain lengths in imidazolium cations, and the electrocatalytic properties (e.g., electrochemically active surface area, catalytic activity, and stability) of the resultant catalysts were systematically investigated. We found that ILs with long cationic chains (C6, C10) efficiently suppressed the formation of nonreactive oxygenated species on Pt; however, at the same time they blocked active Pt sites and led to a lower electrochemically active surface area. It is also disclosed that the catalytic activity strongly correlates with the alkyl chain length of cations, and a distinct dependence of intrinsic activity on the alkyl chain length was identified, with the maximum activity obtained on Pt/C-[C4C1im][NTf2]. The optimum arises from the counterbalance between more efficient suppression of oxygenated species formation on Pt surfaces and more severe passivation of Pt surfaces with elongation of the alkyl chain length in imidazolium cations. Moreover, the presence of an IL can also improve the electrochemical stability of Pt catalysts by suppressing the Pt dissolution, as revealed by combined identical-location transmission electron microscopy (TEM) and in situ inductively coupled plasma mass spectrometry (ICP-MS) analyses.