Your search keyword '"Heiko Gawronski"' showing total 2 results

1. Physisorption versus chemisorption in inelastic electron tunneling spectroscopy: Mode position, intensity, and spatial distribution

Author

Karina Morgenstern and Heiko Gawronski

Subjects

Length scale, Materials science, Inelastic electron tunneling spectroscopy, Condensed Matter Physics, Spectral line, Electronic, Optical and Magnetic Materials, law.invention, Condensed Matter::Materials Science, Adsorption, Physisorption, Chemisorption, law, Physics::Atomic and Molecular Clusters, Molecule, Physics::Chemical Physics, Scanning tunneling microscope, Atomic physics

Abstract

Local vibrational spectra of meta-dichlorobenzene molecules adsorbed on different parts of the Au(111) reconstruction are investigated using a low-temperature scanning tunneling microscope. The spectra show substantial variations on subnanometer length scale. While for the molecule physisorbed on either the hcp or the fcc domain of the reconstruction only low-energy modes are beyond the detection limit, higher-energy modes are observed for the molecule chemisorbed at the elbow site. The different adsorption strengths of the molecules manifest themselves in an energy shift of the modes. These shifts are used to identify through which part the molecule is bonded to the surface.

Published

2014

2. Manipulation and Control of Hydrogen Bond Dynamics in Absorbed Ice Nanoclusters

Author

Karina Morgenstern, Heiko Gawronski, Javier Carrasco, and Angelos Michaelides

Subjects

Models, Molecular, Materials science, Hydrogen bond, Ice, Scanning tunneling spectroscopy, Water, General Physics and Astronomy, Hydrogen Bonding, Electron, Molecular physics, Absorption, Nanostructures, Nanoclusters, law.invention, law, Density functional theory, Deuterium Oxide, Atomic physics, Diffusion (business), Scanning tunneling microscope, Excitation

Abstract

Inelastic electron tunneling is used to explore the dynamics of ice nanoclusters adsorbed on Ag(111). The diffusion of entire nanoclusters or internal hydrogen bond rearrangement can be selectively controlled by injecting electrons either directly into the clusters themselves or indirectly ("indirect inelastic electron tunneling") into the substrate at distances of up to 20 nm from them; a reaction probability that oscillates with the tip-cluster lateral distance presents evidence that surface state electrons mediate the excitation. Density functional theory calculations reveal a strong sensitivity of the computed activation energies of the individual processes to the applied electrical field.

Published

2008