Your search keyword '"Pollmann, E."' showing total 2 results

1. Evaluating strain and doping of Janus MoSSe from phonon mode shifts supported by ab initio DFT calculations.

Author

Schmeink J, Musytschuk V, Pollmann E, Sleziona S, Maas A, Kratzer P, and Schleberger M

Abstract

With the study of Janus monolayer transition metal dichalcogenides, in which one of the two chalcogen layers is replaced by another type of chalcogen atom, research on two-dimensional materials is advancing into new areas. Yet only little is known about this new kind of material class, mainly due to the difficult synthesis. In this work, we synthesize MoSSe monolayers from exfoliated samples and compare their Raman signatures with density functional theory calculations of phonon modes that depend in a nontrivial way on doping and strain. With this as a tool, we can infer limits for the possible combinations of strain and doping levels. This reference data can be applied to all MoSSe Janus samples in order to quickly estimate their strain and doping, providing a reliable tool for future work. In order to narrow down the results for our samples further, we analyze the temperature-dependent photoluminescence spectra and time-correlated single-photon counting measurements. The lifetime of Janus MoSSe monolayers exhibits two decay processes with an average total lifetime of 1.57 ns. Moreover, we find a strong trion contribution to the photoluminescence spectra at low temperature which we attribute to excess charge carriers, corroborating our ab initio calculations.

Published

2023

2. Highly active single-layer MoS 2 catalysts synthesized by swift heavy ion irradiation.

Author

Madauß L, Zegkinoglou I, Vázquez Muiños H, Choi YW, Kunze S, Zhao MQ, Naylor CH, Ernst P, Pollmann E, Ochedowski O, Lebius H, Benyagoub A, Ban-d'Etat B, Johnson ATC, Djurabekova F, Roldan Cuenya B, and Schleberger M

Abstract

Two-dimensional molybdenum-disulfide (MoS2) catalysts can achieve high catalytic activity for the hydrogen evolution reaction upon appropriate modification of their surface. The intrinsic inertness of the compound's basal planes can be overcome by either increasing the number of catalytically active edge sites or by enhancing the activity of the basal planes via a controlled creation of sulfur vacancies. Here, we report a novel method of activating the MoS2 surface using swift heavy ion irradiation. The creation of nanometer-scale structures by an ion beam, in combination with the partial sulfur depletion of the basal planes, leads to a large increase of the number of low-coordinated Mo atoms, which can form bonds with adsorbing species. This results in a decreased onset potential for hydrogen evolution, as well as in a significant enhancement of the electrochemical current density by over 160% as compared to an identical but non-irradiated MoS2 surface.

Published

2018