M
Martin Veselý
Researcher at Institute of Chemical Technology in Prague
Publications - 43
Citations - 549
Martin Veselý is an academic researcher from Institute of Chemical Technology in Prague. The author has contributed to research in topics: Catalysis & Chemistry. The author has an hindex of 10, co-authored 35 publications receiving 319 citations. Previous affiliations of Martin Veselý include Utrecht University.
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Recent Developments on the Single Atom Supported at 2D Materials Beyond Graphene as Catalysts
TL;DR: Two dimensional (2D) layered materials have proven to be crucial platforms for anchored individual and isolated metal atoms acting as active single atom catalysts (SACs) as discussed by the authors.
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Nanoscale chemical imaging of solid–liquid interfaces using tip-enhanced Raman spectroscopy
TL;DR: This work develops plasmonically-active TERS probes with a multilayer metal coating structure that can be successfully used within a liquid environment and demonstrates TERS imaging with nanoscale spatial resolution in a water environment for the first time by employing single-wall carbon nanotubes as a model sample.
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Processing, microstructure and elastic properties of mullite-based ceramic foams prepared by direct foaming with wheat flour
TL;DR: In this paper, the porosity from foam cells (8 −88%), interface density, mean curvature integral density and the related pore size measures (mean chord length and Jeffries size) are determined via impulse excitation.
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On the mechanism of colloidal silica action to improve flow properties of pharmaceutical excipients.
TL;DR: The kinetic aspects of colloidal silica action are investigated, focusing on non-spherical particles of different size, causing the flow properties change over time being dependent on the blend formulation and the component properties.
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Nickel Poisoning of a Cracking Catalyst Unravelled by Single-Particle X-ray Fluorescence-Diffraction-Absorption Tomography.
Marianna Gambino,Martin Veselý,Matthias Filez,Ramon Oord,Dario Ferreira Sanchez,Daniel Grolimund,Nikolai Nesterenko,Delphine Minoux,Marianne Maquet,Florian Meirer,Bert M. Weckhuysen +10 more
TL;DR: Although both particles show similar surface zeolite degradation, the Ni-rich particle displayed higher dealumination and a clear Brønsted acidity drop, and a preferential interaction of Ni, found in co-localization with Fe, with the γ-Al2O3 matrix, leading to the formation of spinel-type hotspots was revealed.