M
Markus Heyde
Researcher at Fritz Haber Institute of the Max Planck Society
Publications - 138
Citations - 4367
Markus Heyde is an academic researcher from Fritz Haber Institute of the Max Planck Society. The author has contributed to research in topics: Scanning tunneling microscope & Oxide. The author has an hindex of 36, co-authored 119 publications receiving 3910 citations. Previous affiliations of Markus Heyde include Max Planck Society & Lawrence Berkeley National Laboratory.
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Control of the charge state of metal atoms on thin MgO films.
Martin Sterrer,Thomas Risse,Umberto Martinez Pozzoni,Livia Giordano,Markus Heyde,Hans-Peter Rust,Gianfranco Pacchioni,Hans-Joachim Freund +7 more
TL;DR: The long-range ordering as well as the scanning tunneling microscopy appearance of single Au atoms on a 3 monolayer thin MgO film can be explained by partial charge transfer from the substrate to Au atoms as predicted recently by density functional theory calculations.
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The Atomic Structure of a Metal‐Supported Vitreous Thin Silica Film
Leonid Lichtenstein,Christin Büchner,Bing Yang,Shamil K. Shaikhutdinov,Markus Heyde,Marek Sierka,Radosław Włodarczyk,Joachim Sauer,Hans-Joachim Freund +8 more
TL;DR: The total pair correlation function of the structural model shows good agreement with diffraction experiments performed on vitreous silica.
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Growth and structure of crystalline silica sheet on Ru(0001)
Daniel Löffler,John J. Uhlrich,Martin Baron,Bing Yang,Xin Yu,Leonid Lichtenstein,Lars Heinke,Christin Büchner,Markus Heyde,Shamil K. Shaikhutdinov,Hans-Joachim Freund,Radosław Włodarczyk,Marek Sierka,Joachim Sauer +13 more
TL;DR: The experimental results in combination with density functional theory calculations provide compelling evidence for the formation of crystalline, double-layer sheet silica weakly bound to a metal substrate.
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Crossover from three-dimensional to two-dimensional geometries of Au nanostructures on thin MgO(001) films: a confirmation of theoretical predictions.
TL;DR: A low-temperature scanning tunneling microscopy study aiming to explore the adsorption properties of Au with respect to the thickness of supported MgO films finds significant differences in the distribution of Au adsorptive sites and in the Au cluster geometry, in line with recent calculations and electron paramagnetic resonance experiments.