van der Waals-corrected Density Functional Theory simulation of adsorption processes on transition-metal surfaces: Xe and graphene on Ni(111)

TL;DR

This paper applies a van der Waals-corrected DFT method to study adsorption of Xe and graphene on Ni(111), providing insights into physisorption and chemisorption interactions with good agreement to experimental data.

Contribution

The study demonstrates the effectiveness of the DFT/vdW-WF2s1 method in accurately modeling adsorption on transition-metal surfaces, including complex graphene interactions.

Findings

Xe prefers top-site adsorption on Ni(111)

The method accurately reproduces experimental adsorption data

Characterization of graphene-Ni(111) bonds using Wannier functions

Abstract

The DFT/vdW-WF2s1 method, recently developed to include the van der Waals interactions in the Density Functional Theory and describe adsorption processes on metal surfaces by taking metal-screening effects into account, is applied to the case of the interaction of Xe and graphene with a transition-metal surface, namely Ni(111). In general the adsorption of rare-gas atoms on metal surfaces is important because is prototypical for physisorption processes. Moreover, the interaction of graphene with Ni(111) is of particular interest for practical applications (efficient and large-scale production of high-quality graphene) and, from a theoretical point of view, is particularly challenging, since it can be described by a delicate interplay between chemisorption and physisorption processes. The first-principles simulation of transition metals require particular care also because they can be viewed as intermediate systems between simple metals and insulating crystals. Even in these cases the method performs well as demonstrated by comparing our results with available experimental data and other theoretical investigations. We confirm that the rare gas Xe atom is preferentially adsorbed on the top-site configuration on the Ni(111) surface too. Our approach based on the use of the Maximally Localized Wannier Functions also allow us to well characterize the bonds between graphene and Ni(111).