Electronic, Mechanical, and Dielectric Properties of Two-Dimensional Atomic Layers of Noble Metals
Files
Date
2017
Journal Title
Journal ISSN
Volume Title
Publisher
Springer New York LLC
Abstract
We present density functional theory-based electronic, mechanical, and dielectric properties of monolayers and bilayers of noble metals (Au, Ag, Cu, and Pt) taken with graphene-like hexagonal structure. The Au, Ag, and Pt bilayers stabilize in AA-stacked configuration, while the Cu bilayer favors the AB stacking pattern. The quantum ballistic conductance of the noble-metal mono- and bilayers is remarkably increased compared with their bulk counterparts. Among the studied systems, the tensile strength is found to be highest for the Pt monolayer and bilayer. The noble metals in mono- and bilayer form show distinctly different electron energy loss spectra and reflectance spectra due to the quantum confinement effect on going from bulk to the monolayer limit. Such tunability of the electronic and dielectric properties of noble metals by reducing the degrees of freedom of electrons offers promise for their use in nanoelectronics and optoelectronics applications. ? 2016, The Minerals, Metals & Materials Society.
Description
Keywords
Degrees of freedom (mechanics), Density (specific gravity), Dielectric properties, Electron energy levels, Electron energy loss spectroscopy, Electronic properties, Energy dissipation, Graphene, Mechanical properties, Metals, Monolayers, Platinum, Precious metals, Silver, Tensile strength, Atomic layer, Ballistic conductance, Electron energy loss spectrum, Hexagonal structures, Quantum confinement effects, Reflectance spectrum, Stacked configuration, Stacking patterns, Density functional theory
Citation
Kapoor, P., Kumar, J., Kumar, A., Kumar, A., & Ahluwalia, P. K. (2017). Electronic, Mechanical, and Dielectric Properties of Two-Dimensional Atomic Layers of Noble Metals. Journal of Electronic Materials, 46(1), 650-659. doi: 10.1007/s11664-016-4864-z