Your search keyword '"Hejral U"' showing total 30 results

1. Composition-Dependent Alloy Nanoparticle Shape Changes under Reaction Conditions: Kinetic and Thermodynamic Effects

Author

Hejral, U., primary, Plessow, P. N., additional, Franz, D., additional, Shipilin, M., additional, Gutowski, O., additional, Rütt, U., additional, Noei, H., additional, Vonk, V., additional, and Stierle, A., additional

Published

2024

2. High-Energy Surface X-ray Diffraction for Fast Surface Structure Determination

Author

Gustafson, J., Shipilin, M., Zhang, C., Stierle, A., Hejral, U., Ruett, U., Gutowski, O., Carlsson, P.-A., Skoglundh, M., and Lundgren, E.

Published

2014

3. Surface optical reflectance combined with x-ray techniques during gas-surface interactions

Author

Albertin, S., Gustafson, J., Zhou, J., Pfaff, S., Shipilin, Mikhail, Blomberg, S., Merte, L. R., Gutowski, O., Dippel, A.-C., Zetterberg, J., Lundgren, E., Hejral, U., Albertin, S., Gustafson, J., Zhou, J., Pfaff, S., Shipilin, Mikhail, Blomberg, S., Merte, L. R., Gutowski, O., Dippel, A.-C., Zetterberg, J., Lundgren, E., and Hejral, U.

Abstract

High energy surface x-ray diffraction (HESXRD), x-ray reflectivity (XRR), mass spectrometry(MS) and surface optical reflectance (SOR) have been combined to simultaneously obtainsub-second information on the surface structure and morphology from a Pd(100) model catalystduringin situoxidation at elevated temperatures and pressures resulting in Pd bulk oxideformation. The results show a strong correlation between the HESXRD and SOR signalintensities during the experiment, enabling phase determination and a time-resolved thicknessestimation of the oxide by HESXRD, complemented by XRR measurements. The experimentsshow a remarkable sensitivity of the SOR to changes in the surface phase and morphology, inparticular to the initial stages of oxidation/reduction. The data imply that SOR can detect theformation of an ultrathin PdO surface oxide layer of only 2–3 Å thickness.

Published

2020

4. High-Resolution X-ray Photoelectron Spectroscopy of an IrO2(110) Film on Ir(100)

Author

Martin, R., primary, Kim, M., additional, Lee, C. J., additional, Mehar, V., additional, Albertin, S., additional, Hejral, U., additional, Merte, L. R., additional, Lundgren, E., additional, Asthagiri, A., additional, and Weaver, J. F., additional

Published

2020

5. Surface optical reflectance combined with x-ray techniques during gas-surface interactions

Author

Albertin, S, primary, Gustafson, J, additional, Zhou, J, additional, Pfaff, S, additional, Shipilin, M, additional, Blomberg, S, additional, Merte, L R, additional, Gutowski, O, additional, Dippel, A-C, additional, Zetterberg, J, additional, Lundgren, E, additional, and Hejral, U, additional

Published

2020

6. Combining high-energy X-ray diffraction with Surface Optical Reflectance and Planar Laser Induced Fluorescence for operando catalyst surface characterization

Author

Pfaff, S., Zhou, J., Hejral, U., Gustafson, J., Shipilin, Mikhail, Albertin, S., Blomberg, S., Gutowski, O., Dippel, A., Lundgren, E., Zetterberg, J., Pfaff, S., Zhou, J., Hejral, U., Gustafson, J., Shipilin, Mikhail, Albertin, S., Blomberg, S., Gutowski, O., Dippel, A., Lundgren, E., and Zetterberg, J.

Abstract

We have combined three techniques, High Energy Surface X-Ray Diffraction (HESXRD), Surface Optical Reflectance, and Planar Laser Induced Fluorescence in an operando study of CO oxidation over a Pd(100) catalyst. We show that these techniques provide useful new insights such as the ability to verify that the finite region being probed by techniques such as HESXRD is representative of the sample surface as a whole. The combination is also suitable to determine when changes in gas composition or surface structure and/or morphology occur and to subsequently correlate them with high temporal resolution. In the study, we confirm previous results which show that the Pd(100) surface reaches high activity before an oxide can be detected. Furthermore, we show that the single crystal catalyst surface does not behave homogeneously, which we attribute to the surface being exposed to inhomogeneous gas conditions in mass transfer limited scenarios.

Published

2019

7. Combining high-energy X-ray diffraction with Surface Optical Reflectance and Planar Laser Induced Fluorescence for operando catalyst surface characterization

Author

Pfaff, S., primary, Zhou, J., additional, Hejral, U., additional, Gustafson, J., additional, Shipilin, M., additional, Albertin, S., additional, Blomberg, S., additional, Gutowski, O., additional, Dippel, A., additional, Lundgren, E., additional, and Zetterberg, J., additional

Published

2019

8. High-Resolution X‑ray Photoelectron Spectroscopy of an IrO2(110) Film on Ir(100).

Author

Martin, R., Kim, M., Lee, C. J., Mehar, V., Albertin, S., Hejral, U., Merte, L. R., Lundgren, E., Asthagiri, A., and Weaver, J. F.

Published

2020

9. Identification of a Catalytically Highly Active Surface Phase for CO Oxidation over PtRh Nanoparticles under Operando Reaction Conditions

Author

Hejral, U., primary, Franz, D., additional, Volkov, S., additional, Francoual, S., additional, Strempfer, J., additional, and Stierle, A., additional

Published

2018

10. The influence of incommensurability on the long-range periodicity of the Pd(100)-(5?5)R27?-PdO(101)

Author

Shipilin, M., Merte, L. R., Gustafson, J., Hejral, U., Martin, N. M., Zhang, C., Lundgren, E., Shipilin, M., Merte, L. R., Gustafson, J., Hejral, U., Martin, N. M., Zhang, C., and Lundgren, E.

Published

2017

11. High-energy x-ray diffraction from surfaces and nanoparticles

Author

Hejral, U., primary, Müller, P., additional, Shipilin, M., additional, Gustafson, J., additional, Franz, D., additional, Shayduk, R., additional, Rütt, U., additional, Zhang, C., additional, Merte, L. R., additional, Lundgren, E., additional, Vonk, V., additional, and Stierle, A., additional

Published

2017

12. Effect of Iron Doping in Ordered Nickel Oxide Thin Film Catalyst for the Oxygen Evolution Reaction.

Author

Etxebarria A, Lopez Luna M, Martini A, Hejral U, Rüscher M, Zhan C, Herzog A, Jamshaid A, Kordus D, Bergmann A, Kuhlenbeck H, and Roldan Cuenya B

Abstract

Water splitting has emerged as a promising route for generating hydrogen as an alternative to conventional production methods. Finding affordable and scalable catalysts for the anodic half-reaction, the oxygen evolution reaction (OER), could help with its industrial widespread implementation. Iron-containing Ni-based catalysts have a competitive performance for the use in commercial alkaline electrolyzers. Due to the complexity of studying the catalysts at working conditions, the active phase and the role that iron exerts in conjunction with Ni are still a matter of investigation. Here, we study this topic with NiO(001) and Ni 0.75 Fe 0.25 O x (001) thin film model electrocatalysts employing surface-sensitive techniques. We show that iron constrains the growth of the oxyhydroxide phase formed on top of the Ni or NiFe oxide, which is considered the active phase for the OER. Besides, operando Raman and grazing incidence X-ray absorption spectroscopy experiments reveal that the presence of iron affects both, the disorder level of the active phase and the oxidative charge around Ni during OER. The observed compositional, structural, and electronic properties of each system have been correlated with their electrochemical performance., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

13. Reversible metal cluster formation on Nitrogen-doped carbon controlling electrocatalyst particle size with subnanometer accuracy.

Author

Timoshenko J, Rettenmaier C, Hursán D, Rüscher M, Ortega E, Herzog A, Wagner T, Bergmann A, Hejral U, Yoon A, Martini A, Liberra E, Monteiro MCO, and Cuenya BR

Abstract

Copper and nitrogen co-doped carbon catalysts exhibit a remarkable behavior during the electrocatalytic CO 2 reduction (CO 2 RR), namely, the formation of metal nanoparticles from Cu single atoms, and their subsequent reversible redispersion. Here we show that the switchable nature of these species holds the key for the on-demand control over the distribution of CO 2 RR products, a lack of which has thus far hindered the wide-spread practical adoption of CO 2 RR. By intermitting pulses of a working cathodic potential with pulses of anodic potential, we were able to achieve a controlled fragmentation of the Cu particles and partial regeneration of single atom sites. By tuning the pulse durations, and by tracking the catalyst's evolution using operando quick X-ray absorption spectroscopy, the speciation of the catalyst can be steered toward single atom sites, ultrasmall metal clusters or large metal nanoparticles, each exhibiting unique CO 2 RR functionalities., (© 2024. The Author(s).)

Published

2024

14. Synergizing Fe 2 O 3 Nanoparticles on Single Atom Fe-N-C for Nitrate Reduction to Ammonia at Industrial Current Densities.

Author

Murphy E, Sun B, Rüscher M, Liu Y, Zang W, Guo S, Chen YH, Hejral U, Huang Y, Ly A, Zenyuk IV, Pan X, Timoshenko J, Cuenya BR, Spoerke ED, and Atanassov P

Abstract

The electrochemical reduction of nitrates (NO 3 - ) enables a pathway for the carbon neutral synthesis of ammonia (NH 3 ), via the nitrate reduction reaction (NO 3 RR), which has been demonstrated at high selectivity. However, to make NH 3 synthesis cost-competitive with current technologies, high NH 3 partial current densities (j NH3 ) must be achieved to reduce the levelized cost of NH 3 . Here, the high NO 3 RR activity of Fe-based materials is leveraged to synthesize a novel active particle-active support system with Fe 2 O 3 nanoparticles supported on atomically dispersed Fe-N-C. The optimized 3×Fe 2 O 3 /Fe-N-C catalyst demonstrates an ultrahigh NO 3 RR activity, reaching a maximum j NH3 of 1.95 A cm -2 at a Faradaic efficiency (FE) for NH 3 of 100% and an NH 3 yield rate over 9 mmol hr -1 cm -2 . Operando XANES and post-mortem XPS reveal the importance of a pre-reduction activation step, reducing the surface Fe 2 O 3 (Fe 3+ ) to highly active Fe 0 sites, which are maintained during electrolysis. Durability studies demonstrate the robustness of both the Fe 2 O 3 particles and Fe-N x sites at highly cathodic potentials, maintaining a current of -1.3 A cm -2 over 24 hours. This work exhibits an effective and durable active particle-active support system enhancing the performance of the NO 3 RR, enabling industrially relevant current densities and near 100% selectivity., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

15. Role of Fe decoration on the oxygen evolving state of Co 3 O 4 nanocatalysts.

Author

Haase FT, Ortega E, Saddeler S, Schmidt FP, Cruz D, Scholten F, Rüscher M, Martini A, Jeon HS, Herzog A, Hejral U, Davis EM, Timoshenko J, Knop-Gericke A, Lunkenbein T, Schulz S, Bergmann A, and Roldan Cuenya B

Abstract

The production of green hydrogen through alkaline water electrolysis is the key technology for the future carbon-neutral industry. Nanocrystalline Co 3 O 4 catalysts are highly promising electrocatalysts for the oxygen evolution reaction and their activity strongly benefits from Fe surface decoration. However, limited knowledge of decisive catalyst motifs at the atomic level during oxygen evolution prevents their knowledge-driven optimization. Here, we employ a variety of operando spectroscopic methods to unveil how Fe decoration increases the catalytic activity of Co 3 O 4 nanocatalysts as well as steer the (near-surface) active state formation. Our study shows a link of the termination-dependent Fe decoration to the activity enhancement and a significantly stronger Co 3 O 4 near-surface (structural) adaptation under the reaction conditions. The near-surface Fe- and Co-O species accumulate an oxidative charge and undergo a reversible bond contraction during the catalytic process. Moreover, our work demonstrates the importance of low coordination surface sites on the Co 3 O 4 host to ensure an efficient Fe-induced activity enhancement, providing another puzzle piece to facilitate optimized catalyst design., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

16. Operando insights into correlating CO coverage and Cu-Au alloying with the selectivity of Au NP-decorated Cu 2 O nanocubes during the electrocatalytic CO 2 reduction.

Author

Rettenmaier C, Herzog A, Casari D, Rüscher M, Jeon HS, Kordus D, Luna ML, Kühl S, Hejral U, Davis EM, Chee SW, Timoshenko J, Alexander DTL, Bergmann A, and Cuenya BR

Abstract

Electrochemical reduction of CO 2 (CO 2 RR) is an attractive technology to reintegrate the anthropogenic CO 2 back into the carbon cycle driven by a suitable catalyst. This study employs highly efficient multi-carbon (C 2+ ) producing Cu 2 O nanocubes (NCs) decorated with CO-selective Au nanoparticles (NPs) to investigate the correlation between a high CO surface concentration microenvironment and the catalytic performance. Structure, morphology and near-surface composition are studied via operando X-ray absorption spectroscopy and surface-enhanced Raman spectroscopy, operando high-energy X-ray diffraction as well as quasi in situ X-ray photoelectron spectroscopy. These operando studies show the continuous evolution of the local structure and chemical environment of our catalysts during reaction conditions. Along with its alloy formation, a CO-rich microenvironment as well as weakened average CO binding on the catalyst surface during CO 2 RR is detected. Linking these findings to the catalytic function, a complex compositional interplay between Au and Cu is revealed in which higher Au loadings primarily facilitate CO formation. Nonetheless, the strongest improvement in C 2+ formation appears for the lowest Au loadings, suggesting a beneficial role of the Au-Cu atomic interaction for the catalytic function in CO 2 RR. This study highlights the importance of site engineering and operando investigations to unveil the electrocatalyst's adaptations to the reaction conditions, which is a prerequisite to understand its catalytic behavior., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2023

17. Formation of Epitaxial PdO(100) During the Oxidation of Pd(100).

Author

Mehar V, Edström H, Shipilin M, Hejral U, Wu C, Kadiri A, Albertin S, Hagman B, von Allmen K, Wiegmann T, Pfaff S, Drnec J, Zetterberg J, Lundgren E, Merte LR, Gustafson J, and Weaver JF

Abstract

The catalytic oxidation of CO and CH 4 can be strongly influenced by the structures of oxide phases that form on metallic catalysts during reaction. Here, we show that an epitaxial PdO(100) structure forms at temperatures above 600 K during the oxidation of Pd(100) by gaseous O atoms as well as exposure to O 2 -rich mixtures at millibar partial pressures. The oxidation of Pd(100) by gaseous O atoms preferentially generates an epitaxial, multilayer PdO(101) structure at 500 K, but initiating Pd(100) oxidation above 600 K causes an epitaxial PdO(100) structure to grow concurrently with PdO(101) and produces a thicker and rougher oxide. We present evidence that this change in the oxidation behavior is caused by a temperature-induced change in the stability of small PdO domains that initiate oxidation. Our discovery of the epitaxial PdO(100) structure may be significant for developing relationships among oxide structure, catalytic activity, and reaction conditions for applications of oxidation catalysis.

Published

2023

18. Deciphering the Structural and Chemical Transformations of Oxide Catalysts during Oxygen Evolution Reaction Using Quick X-ray Absorption Spectroscopy and Machine Learning.

Author

Timoshenko J, Haase FT, Saddeler S, Rüscher M, Jeon HS, Herzog A, Hejral U, Bergmann A, Schulz S, and Roldan Cuenya B

Abstract

Bimetallic transition-metal oxides, such as spinel-like Co x Fe 3- x O 4 materials, are known as attractive catalysts for the oxygen evolution reaction (OER) in alkaline electrolytes. Nonetheless, unveiling the real active species and active states in these catalysts remains a challenge. The coexistence of metal ions in different chemical states and in different chemical environments, including disordered X-ray amorphous phases that all evolve under reaction conditions, hinders the application of common operando techniques. Here, we address this issue by relying on operando quick X-ray absorption fine structure spectroscopy, coupled with unsupervised and supervised machine learning methods. We use principal component analysis to understand the subtle changes in the X-ray absorption near-edge structure spectra and develop an artificial neural network to decipher the extended X-ray absorption fine structure spectra. This allows us to separately track the evolution of tetrahedrally and octahedrally coordinated species and to disentangle the chemical changes and several phase transitions taking place in Co x Fe 3- x O 4 catalysts and on their active surface, related to the conversion of disordered oxides into spinel-like structures, transformation of spinels into active oxyhydroxides, and changes in the degree of spinel inversion in the course of the activation treatment and under OER conditions. By correlating the revealed structural changes with the distinct catalytic activity for a series of Co x Fe 3- x O 4 samples, we elucidate the active species and OER mechanism.

Published

2023

19. Operando Observation of Oxygenated Intermediates during CO Hydrogenation on Rh Single Crystals.

Author

Degerman D, Shipilin M, Lömker P, Goodwin CM, Gericke SM, Hejral U, Gladh J, Wang HY, Schlueter C, Nilsson A, and Amann P

Abstract

The CO hydrogenation reaction over the Rh(111) and (211) surfaces has been investigated operando by X-ray photoelectron spectroscopy at a pressure of 150 mbar. Observations of the resting state of the catalyst give mechanistic insight into the selectivity of Rh for generating ethanol from CO hydrogenation. This study shows that the Rh(111) surface does not dissociate all CO molecules before hydrogenation of the O and C atoms, which allows methoxy and other both oxygenated and hydrogenated species to be visible in the photoelectron spectra.

Published

2022

20. Bridging the Pressure Gap in CO Oxidation.

Author

Blomberg S, Hejral U, Shipilin M, Albertin S, Karlsson H, Hulteberg C, Lömker P, Goodwin C, Degerman D, Gustafson J, Schlueter C, Nilsson A, Lundgren E, and Amann P

Abstract

Performing fundamental operando catalysis studies under realistic conditions is a key to further develop and increase the efficiency of industrial catalysts. Operando X-ray photoelectron spectroscopy (XPS) experiments have been limited to pressures, and the relevance for industrial applications has been questioned. Herein, we report on the CO oxidation experiment on Pd(100) performed at a total pressure of 1 bar using XPS. We investigate the light-off regime and the surface chemical composition at the atomistic level in the highly active phase. Furthermore, the observed gas-phase photoemission peaks of CO 2 , CO, and O 2 indicate that the kinetics of the reaction during the light-off regime can be followed operando , and by studying the reaction rate of the reaction, the activation energy is calculated. The reaction was preceded by an in situ oxidation study in 7% O 2 in He and a total pressure of 70 mbar to confirm the surface sensitivity and assignment of the oxygen-induced photoemission peaks. However, oxygen-induced photoemission peaks were not observed during the reaction studies, but instead, a metallic Pd phase is present in the highly active regime under the conditions applied. The novel XPS setup utilizes hard X-rays to enable high-pressure studies, combined with a grazing incident angle to increase the surface sensitivity of the measurement. Our findings demonstrate the possibilities of achieving chemical information of the catalyst, operando , on an atomistic level, under industrially relevant conditions., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021

21. Selectivity Control of Cu Nanocrystals in a Gas-Fed Flow Cell through CO 2 Pulsed Electroreduction.

Author

Jeon HS, Timoshenko J, Rettenmaier C, Herzog A, Yoon A, Chee SW, Oener S, Hejral U, Haase FT, and Roldan Cuenya B

Abstract

In this study, we have taken advantage of a pulsed CO 2 electroreduction reaction (CO 2 RR) approach to tune the product distribution at industrially relevant current densities in a gas-fed flow cell. We compared the CO 2 RR selectivity of Cu catalysts subjected to either potentiostatic conditions (fixed applied potential of -0.7 V RHE ) or pulsed electrolysis conditions (1 s pulses at oxidative potentials ranging from E an = 0.6 to 1.5 V RHE , followed by 1 s pulses at -0.7 V RHE ) and identified the main parameters responsible for the enhanced product selectivity observed in the latter case. Herein, two distinct regimes were observed: (i) for E an = 0.9 V RHE we obtained 10% enhanced C 2 product selectivity (FE C 2 H 4 = 43.6% and FE C 2 H 5 OH = 19.8%) in comparison to the potentiostatic CO 2 RR at -0.7 V RHE (FE C 2 H 4 = 40.9% and FE C 2 H 5 OH = 11%), (ii) while for E an = 1.2 V RHE , high CH 4 selectivity (FE CH 4 = 48.3% vs 0.1% at constant -0.7 V RHE ) was observed. Operando spectroscopy (XAS, SERS) and ex situ microscopy (SEM and TEM) measurements revealed that these differences in catalyst selectivity can be ascribed to structural modifications and local pH effects. The morphological reconstruction of the catalyst observed after pulsed electrolysis with E an = 0.9 V RHE , including the presence of highly defective interfaces and grain boundaries, was found to play a key role in the enhancement of the C 2 product formation. In turn, pulsed electrolysis with E an = 1.2 V RHE caused the consumption of OH - species near the catalyst surface, leading to an OH-poor environment favorable for CH 4 production.

Published

2021

22. The Structure of the Active Pd State During Catalytic Carbon Monoxide Oxidization.

Author

Goodwin CM, Shipilin M, Albertin S, Hejral U, Lömker P, Wang HY, Blomberg S, Degerman D, Schlueter C, Nilsson A, Lundgren E, and Amann P

Abstract

Using grazing incidence X-rays and X-ray photoelectron spectroscopy during the mass transfer limited catalytic oxidation of CO, the long-range surface structure of Pd(100) was investigated. Under the reaction conditions of 50:4 O 2 to CO, 300 mbar pressure, and temperatures between 200 and 450 °C, the surface structure resulting from oxidation and the subsequent oxide reduction was elucidated. The reduction cycle was halted, and while under reaction conditions, angle-dependent X-ray photoelectron spectroscopy close to the critical angle of Pd and modeling of the data was performed. Two proposed models for the system were compared. The suggestion with the metallic islands formed on top of the oxide island was shown to be consistent with the data.

Published

2021

23. High energy surface x-ray diffraction applied to model catalyst surfaces at work.

Author

Hejral U, Shipilin M, Gustafson J, Stierle A, and Lundgren E

Abstract

Catalysts are materials that accelerate the rate of a desired chemical reaction. As such, they constitute an integral part in many applications ranging from the production of fine chemicals in chemical industry to exhaust gas treatment in vehicles. Accordingly, it is of utmost economic interest to improve catalyst efficiency and performance, which requires an understanding of the interplay between the catalyst structure, the gas phase and the catalytic activity under realistic reaction conditions at ambient pressures and elevated temperatures. In recent years efforts have been made to increasingly develop techniques that allow for investigating model catalyst samples under conditions closer to those of real technical catalysts. One of these techniques is high energy surface x-ray diffraction (HESXRD), which uses x-rays with photon energies typically in the range of 70-80 keV. HESXRD allows a fast data collection of three dimensional reciprocal space for the structure determination of model catalyst samples under operando conditions and has since been used for the investigation of an increasing number of different model catalysts. In this article we will review general considerations of HESXRD including its working principle for different model catalyst samples and the experimental equipment required. An overview over HESXRD investigations performed in recent years will be given, and the advantages of HESXRD with respect to its application to different model catalyst samples will be presented. Moreover, the combination of HESXRD with other operando techniques such as in situ mass spectrometry, planar laser-induced fluorescence and surface optical reflectance will be discussed. The article will close with an outlook on future perspectives and applications of HESXRD.

Published

2021

24. High-Resolution X-ray Photoelectron Spectroscopy of an IrO 2 (110) Film on Ir(100).

Author

Martin R, Kim M, Lee CJ, Mehar V, Albertin S, Hejral U, Merte LR, Lundgren E, Asthagiri A, and Weaver JF

Abstract

High-resolution X-ray photoelectron spectroscopy (XPS) and density functional theory (DFT) were used to characterize IrO 2 (110) films on Ir(100) with stoichiometric as well as OH-rich terminations. Core-level Ir 4f and O 1s peaks were identified for the undercoordinated Ir and O atoms and bridging and on-top OH groups at the IrO 2 (110) surfaces. Peak assignments were validated by comparison of the core-level shifts determined experimentally with those computed using DFT, quantitative analysis of the concentrations of surface species, and the measured variation of the Ir 4f peak intensities with photoelectron kinetic energy. We show that exposure of the IrO 2 (110) surface to O 2 near room temperature produces a large quantity of on-top OH groups because of reaction of background H 2 with the surface. The peak assignments made in this study can serve as a foundation for future experiments designed to utilize XPS to uncover atomic-level details of the surface chemistry of IrO 2 (110).

Published

2020

25. Combining synchrotron light with laser technology in catalysis research.

Author

Blomberg S, Zetterberg J, Gustafson J, Zhou J, Shipilin M, Pfaff S, Hejral U, Carlsson PA, Gutowski O, Bertram F, and Lundgren E

Abstract

High-energy surface X-ray diffraction (HESXRD) provides surface structural information with high temporal resolution, facilitating the understanding of the surface dynamics and structure of the active phase of catalytic surfaces. The surface structure detected during the reaction is sensitive to the composition of the gas phase close to the catalyst surface, and the catalytic activity of the sample itself may affect the surface structure, which in turn may complicate the assignment of the active phase. For this reason, planar laser-induced fluorescence (PLIF) and HESXRD have been combined during the oxidation of CO over a Pd(100) crystal. PLIF complements the structural studies with an instantaneous two-dimensional image of the CO 2 gas phase in the vicinity of the active model catalyst. Here the combined HESXRD and PLIF operando measurements of CO oxidation over Pd(100) are presented, allowing for an improved assignment of the correlation between sample structure and the CO 2 distribution above the sample surface with sub-second time resolution., (open access.)

Published

2018

26. Thermal reduction of ceria nanostructures on rhodium(111) and re-oxidation by CO 2 .

Author

Schaefer A, Hagman B, Höcker J, Hejral U, Flege JI, and Gustafson J

Abstract

The thermal reduction of cerium oxide nanostructures deposited on a rhodium(111) single crystal surface and the re-oxidation of the structures by exposure to CO2 were investigated. Two samples are compared: a rhodium surface covered to ≈60% by one to two O-Ce-O trilayer high islands and a surface covered to ≈65% by islands of four O-Ce-O trilayer thickness. Two main results stand out: (1) the thin islands reduce at a lower temperature (870-890 K) and very close to Ce2O3, while the thicker islands need higher temperature for reduction and only reduce to about CeO1.63 at a maximum temperature of 920 K. (2) Ceria is re-oxidized by CO2. The rhodium surface promotes the re-oxidation by splitting the CO2 and thus providing atomic oxygen. The process shows a clear temperature dependence. The maximum oxidation state of the oxide reached by re-oxidation with CO2 differs for the two samples, showing that the thinner structures require a higher temperature for re-oxidation with CO2. Adsorbed carbon species, potentially blocking reactive sites, desorb from both samples at the same temperature and cannot be the sole origin for the observed differences. Instead, an intrinsic property of the differently sized CeOx islands must be at the origin of the observed temperature dependence of the re-oxidation by CO2.

Published

2018

27. Novel in Situ Techniques for Studies of Model Catalysts.

Author

Lundgren E, Zhang C, Merte LR, Shipilin M, Blomberg S, Hejral U, Zhou J, Zetterberg J, and Gustafson J

Abstract

Motivated mainly by catalysis, gas-surface interaction between single crystal surfaces and molecules has been studied for decades. Most of these studies have been performed in well-controlled environments and have been instrumental for the present day understanding of catalysis, providing information on surface structures, adsorption sites, and adsorption and desorption energies relevant for catalysis. However, the approach has been criticized for being too far from a catalyst operating under industrial conditions at high temperatures and pressures. To this end, a significant amount of effort over the years has been used to develop methods to investigate catalysts at more realistic conditions under operating conditions. One result from this effort is a vivid and sometimes heated discussion concerning the active phase for the seemingly simple CO oxidation reaction over the Pt-group metals in the literature. In recent years, we have explored the possibilities to perform experiments at conditions closer to those of a technical catalyst, in particular at increased pressures and temperatures. In this contribution, results from catalytic CO oxidation over a Pd(100) single crystal surface using Near Ambient Pressure X-ray Photo emission Spectroscopy (NAPXPS), Planar Laser-Induced Fluorescence (PLIF), and High Energy Surface X-ray Diffraction (HESXRD) are presented, and the strengths and weaknesses of the experimental techniques are discussed. Armed with structural knowledge from ultrahigh vacuum experiments, the presence of adsorbed molecules and gas-phase induced surface structures can be identified and related to changes in the reactivity or to reaction induced gas-flow limitations. In particular, the application of PLIF to catalysis allows one to visualize how the catalyst itself changes the gas composition close to the model catalyst surface upon ignition, and relate this to the observed surface structures. The effect obscures a straightforward relation between the active phase and the activity, since in the case of CO oxidation, the gas-phase close to the model catalyst surface is shown to be significantly more oxidizing than far away from the catalyst. We show that surface structural knowledge from UHV experiments and the composition of the gas phase close to the catalyst surface are crucial to understand structure-function relationships at semirealistic conditions. In the particular case of Pd, we argue that the surface structure of the PdO(101) has a significant influence on the activity, due to the presence of Coordinatively Unsaturated Sites (CUS) Pd atoms, similar to undercoordinated Ru and Ir atoms found for RuO 2 (110) and IrO 2 (110), respectively.

Published

2017

28. Non-uniform nanosecond gate-delay of hybrid pixel detectors.

Author

Shayduk R, Pennicard D, Krausert K, Gaal P, Volkov S, Vonk V, Hejral U, Jankowski M, Reinhardt M, Leitenberger W, and Stierle A

Abstract

A simple experiment to characterize the gating properties of X-ray area detectors using pulsed X-ray sources is presented. For a number of time-resolved experiments the gating uniformity of area detectors is important. Relative gating delays between individual modules and readout chips of PILATUS2 series area X-ray detectors have been observed. For three modules of a PILATUS 300K-W unit the maximum gating offset between the modules is found to be as large as 30 ns. On average, the first photosensor module is found to be triggered 15 ns and 30 ns later than the second and the third modules, respectively.

Published

2017

29. Tracking the shape-dependent sintering of platinum-rhodium model catalysts under operando conditions.

Author

Hejral U, Müller P, Balmes O, Pontoni D, and Stierle A

Abstract

Nanoparticle sintering during catalytic reactions is a major cause for catalyst deactivation. Understanding its atomic-scale processes and finding strategies to reduce it is of paramount scientific and economic interest. Here, we report on the composition-dependent three-dimensional restructuring of epitaxial platinum-rhodium alloy nanoparticles on alumina during carbon monoxide oxidation at 550 K and near-atmospheric pressures employing in situ high-energy grazing incidence x-ray diffraction, online mass spectrometry and a combinatorial sample design. For platinum-rich particles our results disclose a dramatic reaction-induced height increase, accompanied by a corresponding reduction of the total particle surface coverage. We find this restructuring to be progressively reduced for particles with increasing rhodium composition. We explain our observations by a carbon monoxide oxidation promoted non-classical Ostwald ripening process during which smaller particles are destabilized by the heat of reaction. Its driving force lies in the initial particle shape which features for platinum-rich particles a kinetically stabilized, low aspect ratio.

Published

2016

30. In situ oxidation study of Pd-Rh nanoparticles on MgAl₂O₄(001).

Author

Müller P, Hejral U, Rütt U, and Stierle A

Abstract

Alloy nanoparticles on oxide supports are widely used as heterogeneous catalysts in reactions involving oxygen. Here we discuss the oxidation behavior of Pd-Rh alloy nanoparticles on MgAl2O4(001) supports with a particle diameter from 6-11 nm. As an In situ tool, we employed high energy grazing incidence X-ray diffraction at a photon energy of 85 keV. We find that physical vapor deposited Pd-Rh nanoparticles grow epitaxially on MgAl2O4(001) with a truncated octahedral shape over the whole concentration range. During our systematic oxidation experiments performed at 670 K in the pressure range from 10(-3) to 0.1 mbar, we observe for Rh containing nanoparticles the formation of two different Rh oxide phases, namely RhO2 and a spinel-like Rh3O4 phase. PdO formation is only observed for pure Pd nanoparticles. This oxidation induced segregation behavior is also reflected in the oxidation induced enlargement of the average nanoparticle lattice parameter towards to value for pure Pd. Our results have ramifications for the phase separation behavior of alloy nanocatalysts under varying reducing and oxidizing environments.

Published

2014