Your search keyword '"Niggas, A."' showing total 3 results

1. The role of contaminations in ion beam spectroscopy with freestanding 2D materials: A study on thermal treatment.

Author

Niggas, A., Schwestka, J., Creutzburg, S., Gupta, T., Eder, D., Bayer, B. C., Aumayr, F., and Wilhelm, R. A.

Subjects

*ION beams, *CHARGE exchange, *ION exchange (Chemistry), *SPECTROMETRY, *ENERGY dissipation, *NUCLEAR magnetic resonance spectroscopy

Abstract

As surface-only materials, freestanding 2D materials are known to have a high level of contamination—mostly in the form of hydrocarbons, water, and residuals from production and exfoliation. For well-designed experiments, it is of particular importance to develop effective cleaning procedures, especially since standard surface science techniques are typically not applicable. We perform ion spectroscopy with highly charged ions transmitted through freestanding atomically thin materials and present two techniques to achieve clean samples, both based on thermal treatment. Ion charge exchange and energy loss are used to analyze the degree of sample contamination. We find that even after cleaning, heavily contaminated spots remain on single layer graphene. The contamination coverage, however, clusters in strand-like structures leaving large clean areas. We present a way to discriminate clean from contaminated areas with our ion beam spectroscopy if the heterogeneity of the surface is increased sufficiently enough. We expect a similar discrimination to be necessary in most other experimental techniques. [ABSTRACT FROM AUTHOR]

Published

2020

2. Peeling graphite layer by layer reveals the charge exchange dynamics of ions inside a solid.

Author

Niggas, Anna, Creutzburg, Sascha, Schwestka, Janine, Wöckinger, Benjamin, Gupta, Tushar, Grande, Pedro L., Eder, Dominik, Marques, José P., Bayer, Bernhard C., Aumayr, Friedrich, Bennett, Robert, and Wilhelm, Richard A.

Subjects

*GRAPHITE, *CHARGE exchange, *ELECTRONS, *ENERGY transfer, *GRAPHENE

Abstract

Over seventy years ago, Niels Bohr described how the charge state of an atomic ion moving through a solid changes dynamically as a result of electron capture and loss processes, eventually resulting in an equilibrium charge state. Although obvious, this process has so far eluded direct experimental observation. By peeling a solid, such as graphite, layer by layer, and studying the transmission of highly charged ions through single-, bi- and trilayer graphene, we can now observe dynamical changes in ion charge states with monolayer precision. In addition we present a first-principles approach based on the virtual photon model for interparticle energy transfer to corroborate our findings. Our model that uses a Gaussian shaped dynamic polarisability rather than a spatial delta function is a major step in providing a self-consistent description for interparticle de-excitation processes at the limit of small separations. Ion-solid interactions are governed by a range of complex processes the direct experimental observation of which pose their own set of challenges. Here, the authors present a joint experimental and first-principles approach to study and describe the underlying mechanism of electron capture for an ion travelling through layers of graphene with monolayer precision. [ABSTRACT FROM AUTHOR]

Published

2021

3. Charge-Exchange-Driven Low-Energy Electron Splash Induced by Heavy Ion Impact on Condensed Matter

Author

Marika Schleberger, Roland Kozubek, Janine Schwestka, Richard A. Wilhelm, Anna Niggas, Sascha Creutzburg, Friedrich Aumayr, and René Heller

Subjects

0301 basic medicine, Physics, 030103 biophysics, Splash, Condensed matter physics, viruses, Electron, Physik (inkl. Astronomie), biochemical phenomena, metabolism, and nutrition, digestive system, 01 natural sciences, 7. Clean energy, humanities, Ion, 03 medical and health sciences, Low energy, embryonic structures, 0103 physical sciences, Radiation damage, General Materials Science, Heavy ion, Physical and Theoretical Chemistry, 010306 general physics, Charge exchange

Abstract

Low-energy electrons (LEEs) are of great relevance for ion-induced radiation damage in cells and genes. We show that charge exchange of ions leads to LEE emission upon impact on condensed matter. By using a graphene monolayer as a simple model system for condensed organic matter and utilizing slow highly charged ions (HCIs) as projectiles, we highlight the importance of charge exchange alone for LEE emission. We find a large number of ejected electrons resulting from individual ion impacts (up to 80 electrons/ion for Xe40+). More than 90% of emitted electrons have energies well below 15 eV. This “splash” of low-energy electrons is interpreted as the consequence of ion deexcitation via an interatomic Coulombic decay (ICD) process.