4 research outputs found
Graphene Coatings: Probing the Limits of the One Atom Thick Protection Layer
The limitations of graphene as an effective corrosion-inhibiting coating on metal surfaces, here exemplified by the hex-reconstructed Pt(100) surface, are probed by scanning tunneling microscopy measurements and density functional theory calculations. While exposure of small molecules directly onto the Pt(100) surface will lift the reconstruction, a single graphene layer is observed to act as an effective coating, protecting the reactive surface from O<sub>2</sub> exposure and thus preserving the reconstruction underneath the graphene layer in O<sub>2</sub> pressures as high as 10<sup>–4</sup> mbar. A similar protective effect against CO is observed at CO pressures below 10<sup>–6</sup> mbar. However, at higher pressures CO is observed to intercalate under the graphene coating layer, thus lifting the reconstruction. The limitations of the coating effect are further tested by exposure to hot atomic hydrogen. While the coating can withstand these extreme conditions for a limited amount of time, after substantial exposure, the Pt(100) reconstruction is lifted. Annealing experiments and density functional theory calculations demonstrate that the basal plane of the graphene stays intact and point to a graphene-mediated mechanism for the H-induced lifting of the reconstruction
Chiral Induction with Chiral Conformational Switches in the Limit of Low “Sergeants to Soldiers” Ratio
Molecular-level insights into chiral adsorption phenomena are highly relevant within the fields of asymmetric heterogeneous catalysis or chiral separation and may contribute to understand the origins of homochirality in nature. Here, we investigate chiral induction by the “sergeants and soldiers” mechanism for an oligo(phenylene ethynylene) based chiral conformational switch by coadsorbing it with an intrinsically chiral seed on Au(111). Through statistical analysis of scanning tunneling microscopy (STM) data, we demonstrate successful chiral induction with a very low concentration of seeding molecules down to 3%. The microscopic mechanism for the observed chiral induction is suggested to involve nucleation of the intrinsically chiral seeds, allowing for effective transfer and amplification of chirality to large numbers of soldier target molecules
Scanning Tunneling Microscopy Reveals Single-Molecule Insights into the Self-Assembly of Amyloid Fibrils
Many severe diseases are associated with amyloid fibril deposits in the body caused by protein misfolding. Structural information on amyloid fibrils is accumulating rapidly, but little is known about the assembly of peptides into fibrils at the level of individual molecules. Here we investigate self-assembly of the fibril-forming tetrapeptides KFFE and KVVE on a gold surface under ultraclean vacuum conditions using scanning tunneling microscopy. Combined with restrained molecular dynamics modeling, we identify peptide arrangements with interesting similarities to fibril structures. By resolving individual peptide residues and revealing conformational heterogeneities and dynamics, we demonstrate how conformational correlations may be involved in cooperative fibril growth. Most interestingly, intermolecular interactions prevail over intramolecular interactions, and assembly of the phenyl-rich KFFE peptide appears not to be dominated by π–π interactions. This study offers interesting perspectives for obtaining fundamental single-molecule insights into fibril formation using a surface science approach to study idealized model systems
Ethanol Diffusion on Rutile TiO<sub>2</sub>(110) Mediated by H Adatoms
We have studied the diffusion of ethanol on rutile TiO<sub>2</sub>(110)–(1 × 1) by high-resolution scanning tunneling
microscopy
(STM) measurements and density functional theory (DFT) calculations.
Time-lapsed STM images recorded at ∼200 K revealed the diffusion
of ethanol molecules both parallel and perpendicular to the rows of
surface Ti atoms. The diffusion of ethanol molecules perpendicular
to the rows of surface Ti atoms was found to be mediated by H adatoms
in the rows of bridge-bonded O (O<sub>br</sub>) atoms similarly to
previous results obtained for water monomers. In contrast, the diffusion
of H adatoms across the Ti rows, mediated by ethanol molecules, was
observed only very rarely and exclusively on fully hydrogenated TiO<sub>2</sub>(110) surfaces. Possible reasons why the diffusion of H adatoms
across the Ti rows mediated by ethanol molecules occurs less frequently
than the cross-row diffusion of ethanol molecules mediated by H adatoms
are discussed