Your search keyword '"Johannes, Bernardi"' showing total 7 results

1. Surface Anchoring and Active Sites of [Mo3S13]2– Clusters as Co-Catalysts for Photocatalytic Hydrogen Evolution

Author

Samar Batool, Sreejith P. Nandan, Stephen Nagaraju Myakala, Ashwene Rajagopal, Jasmin S. Schubert, Pablo Ayala, Shaghayegh Naghdi, Hikaru Saito, Johannes Bernardi, Carsten Streb, Alexey Cherevan, and Dominik Eder

Subjects

General Chemistry, Catalysis

Published

2022

2. Reaction Modes on a Single Catalytic Particle: Nanoscale Imaging and Micro-Kinetic Modeling

Author

Johannes Zeininger, Maximilian Raab, Yuri Suchorski, Sebastian Buhr, Michael Stöger-Pollach, Johannes Bernardi, and Günther Rupprechter

Subjects

General Chemistry, Catalysis

Abstract

The kinetic behavior of individual Rh(

Published

2022

3. Steering the Methane Dry Reforming Reactivity of Ni/La2O3 Catalysts by Controlled In Situ Decomposition of Doped La2NiO4 Precursor Structures

Author

Simon Penner, Bernhard Klötzer, Marc Heggen, Yuanxu Gao, Aligholi Niaei, Andrew Doran, Nicolas Bonmassar, Aleksander Gurlo, Ali Farzi, Albert Gili, Sebastian Praetz, Lukas Schlicker, Maged F. Bekheet, Sabine Schwarz, Parastoo Delir Kheyrollahi Nezhad, and Johannes Bernardi

Subjects

X-ray absorption spectroscopy, Materials science, Carbon dioxide reforming, 010405 organic chemistry, Analytical chemistry, General Chemistry, Crystal structure, engineering.material, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Tetragonal crystal system, Ruddlesden-Popper phase, ddc:540, engineering, Reactivity (chemistry), Monoclinic crystal system, Perovskite (structure)

Abstract

The influence of A- and/or B-site doping of Ruddlesden-Popper perovskite materials on the crystal structure, stability, and dry reforming of methane (DRM) reactivity of specific A2BO4 phases (A = La, Ba; B = Cu, Ni) has been evaluated by a combination of catalytic experiments, in situ X-ray diffraction, X-ray absorption spectroscopy (XAS), X-ray photoelectron spectroscopy (XPS), and aberration-corrected electron microscopy. At room temperature, B-site doping of La2NiO4 with Cu stabilizes the orthorhombic structure (Fmmm) of the perovskite, while A-site doping with Ba yields a tetragonal space group (I4/mmm). We observed the orthorhombic-to-tetragonal transformation above 170 °C for La2Ni0.9Cu0.1O4 and La2Ni0.8Cu0.2O4, slightly higher than for undoped La2NiO4. Loss of oxygen in interstitial sites of the tetragonal structure causes further structure transformations for all samples before decomposition in the temperature range of 400 °C-600 °C. Controlled in situ decomposition of the parent or A/B-site doped perovskite structures in a DRM mixture (CH4:CO2 = 1:1) in all cases yields an active phase consisting of exsolved nanocrystalline metallic Ni particles in contact with hexagonal La2O3 and a mixture of (oxy)carbonate phases (hexagonal and monoclinic La2O2CO3, BaCO3). Differences in the catalytic activity evolve because of (i) the in situ formation of Ni-Cu alloy phases (in a composition of >7:1 = Ni:Cu) for La2Ni0.9Cu0.1O4, La2Ni0.8Cu0.2O4, and La1.8Ba0.2Ni0.9Cu0.1O4, (ii) the resulting Ni particle size and amount of exsolved Ni, and (iii) the inherently different reactivity of the present (oxy)carbonate species. Based on the onset temperature of catalytic DRM activity, the latter decreases in the order of La2Ni0.9Cu0.1O4 ∼ La2Ni0.8Cu0.2O4 ≥ La1.8Ba0.2Ni0.9Cu0.1O4 > La2NiO4 > La1.8Ba0.2NiO4. Simple A-site doped La1.8Ba0.2NiO4 is essentially DRM inactive. The Ni particle size can be efficiently influenced by introducing Ba into the A site of the respective Ruddlesden-Popper structures, allowing us to control the Ni particle size between 10 nm and 30 nm both for simple B-site and A-site doped structures. Hence, it is possible to steer both the extent of the metal-oxide-(oxy)carbonate interface and its chemical composition and reactivity. Counteracting the limitation of the larger Ni particle size, the activity can, however, be improved by additional Cu-doping on the B-site, enhancing the carbon reactivity. Exemplified for the La2NiO4 based systems, we show how the delicate antagonistic balance of doping with Cu (rendering the La2NiO4 structure less stable and suppressing coking by efficiently removing surface carbon) and Ba (rendering the La2NiO4 structure more stable and forming unreactive surface or interfacial carbonates) can be used to tailor prospective DRM-active catalysts.

Published

2020

4. Who Does the Job? How Copper Can Replace Noble Metals in Sustainable Catalysis by the Formation of Copper-Mixed Oxide Interfaces

Author

Christoph W. Thurner, Nicolas Bonmassar, Daniel Winkler, Leander Haug, Kevin Ploner, Parastoo Delir Kheyrollahi Nezhad, Xaver Drexler, Asghar Mohammadi, Peter A. van Aken, Julia Kunze-Liebhäuser, Aligholi Niaei, Johannes Bernardi, Bernhard Klötzer, and Simon Penner

Subjects

General Chemistry, Catalysis

Abstract

Following the need for an innovative catalyst and material design in catalysis, we provide a comparative approach using pure and Pd-doped LaCu

Published

2022

5. Surface Anchoring and Active Sites of [Mo

Author

Samar, Batool, Sreejith P, Nandan, Stephen Nagaraju, Myakala, Ashwene, Rajagopal, Jasmin S, Schubert, Pablo, Ayala, Shaghayegh, Naghdi, Hikaru, Saito, Johannes, Bernardi, Carsten, Streb, Alexey, Cherevan, and Dominik, Eder

Abstract

Achieving light-driven splitting of water with high efficiency remains a challenging task on the way to solar fuel exploration. In this work, to combine the advantages of heterogeneous and homogeneous photosystems, we covalently anchor noble-metal- and carbon-free thiomolybdate [Mo

Published

2022

6. In Situ-Determined Catalytically Active State of LaNiO3 in Methane Dry Reforming

Author

Nicolas Bonmassar, Albert Gili, Andrew Doran, Aleksander Gurlo, Yuanxu Gao, Bernhard Klötzer, Maged F. Bekheet, Marc Heggen, Simon Penner, Johannes Bernardi, and Lukas Schlicker

Subjects

In situ, Materials science, Carbon dioxide reforming, 010405 organic chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Catalysis, Methane, 0104 chemical sciences, chemistry.chemical_compound, Chemical engineering, Polymorphism (materials science), chemistry, Active state, Phase diagram

Abstract

Quantitative in situ X-ray diffraction in combination with catalytic tests in dry reforming of methane (DRM) has been performed to unveil the strong structural dynamics of LaNiO3 catalysts during t...

Published

2019

7. Steering the Methane Dry Reforming Reactivity of Ni/La

Author

Maged F, Bekheet, Parastoo, Delir Kheyrollahi Nezhad, Nicolas, Bonmassar, Lukas, Schlicker, Albert, Gili, Sebastian, Praetz, Aleksander, Gurlo, Andrew, Doran, Yuanxu, Gao, Marc, Heggen, Aligholi, Niaei, Ali, Farzi, Sabine, Schwarz, Johannes, Bernardi, Bernhard, Klötzer, and Simon, Penner

Subjects

Ruddlesden−Popper phase, in situ X-ray diffraction, copper, phase transformation, in situ decomposition, perovskite, Research Article

Abstract

The influence of A- and/or B-site doping of Ruddlesden–Popper perovskite materials on the crystal structure, stability, and dry reforming of methane (DRM) reactivity of specific A2BO4 phases (A = La, Ba; B = Cu, Ni) has been evaluated by a combination of catalytic experiments, in situ X-ray diffraction, X-ray absorption spectroscopy (XAS), X-ray photoelectron spectroscopy (XPS), and aberration-corrected electron microscopy. At room temperature, B-site doping of La2NiO4 with Cu stabilizes the orthorhombic structure (Fmmm) of the perovskite, while A-site doping with Ba yields a tetragonal space group (I4/mmm). We observed the orthorhombic-to-tetragonal transformation above 170 °C for La2Ni0.9Cu0.1O4 and La2Ni0.8Cu0.2O4, slightly higher than for undoped La2NiO4. Loss of oxygen in interstitial sites of the tetragonal structure causes further structure transformations for all samples before decomposition in the temperature range of 400 °C–600 °C. Controlled in situ decomposition of the parent or A/B-site doped perovskite structures in a DRM mixture (CH4:CO2 = 1:1) in all cases yields an active phase consisting of exsolved nanocrystalline metallic Ni particles in contact with hexagonal La2O3 and a mixture of (oxy)carbonate phases (hexagonal and monoclinic La2O2CO3, BaCO3). Differences in the catalytic activity evolve because of (i) the in situ formation of Ni–Cu alloy phases (in a composition of >7:1 = Ni:Cu) for La2Ni0.9Cu0.1O4, La2Ni0.8Cu0.2O4, and La1.8Ba0.2Ni0.9Cu0.1O4, (ii) the resulting Ni particle size and amount of exsolved Ni, and (iii) the inherently different reactivity of the present (oxy)carbonate species. Based on the onset temperature of catalytic DRM activity, the latter decreases in the order of La2Ni0.9Cu0.1O4 ∼ La2Ni0.8Cu0.2O4 ≥ La1.8Ba0.2Ni0.9Cu0.1O4 > La2NiO4 > La1.8Ba0.2NiO4. Simple A-site doped La1.8Ba0.2NiO4 is essentially DRM inactive. The Ni particle size can be efficiently influenced by introducing Ba into the A site of the respective Ruddlesden–Popper structures, allowing us to control the Ni particle size between 10 nm and 30 nm both for simple B-site and A-site doped structures. Hence, it is possible to steer both the extent of the metal-oxide-(oxy)carbonate interface and its chemical composition and reactivity. Counteracting the limitation of the larger Ni particle size, the activity can, however, be improved by additional Cu-doping on the B-site, enhancing the carbon reactivity. Exemplified for the La2NiO4 based systems, we show how the delicate antagonistic balance of doping with Cu (rendering the La2NiO4 structure less stable and suppressing coking by efficiently removing surface carbon) and Ba (rendering the La2NiO4 structure more stable and forming unreactive surface or interfacial carbonates) can be used to tailor prospective DRM-active catalysts.

Published

2020