Graphene Layer Morphology as an Indicator of the Metals Alloy Formation at the Interface

TL;DR

This study investigates how the morphology of graphene layers indicates the formation of metal alloys at interfaces, revealing new insights into alloy formation mechanisms through combined experimental and theoretical analysis.

Contribution

It provides new understanding of alloy formation at graphene-metal interfaces using STM and DFT, specifically for Mn intercalation in Ru(0001) and Ir(111).

Findings

Mn forms a pseudomorphic layer on Ru(0001) under buckled graphene.

MnIr alloy forms beneath flat graphene on Ir(111).

Results explain alloy formation mechanisms at interfaces.

Abstract

The intercalation of different species in graphene-metal interfaces is widely used to stabilise the artificial phases of different materials. However, formation of the surface alloys upon the guest-metal intercalation is still an open question, which is very important for the fabrication of graphene-based interfaces with desired properties. Here, the widely studied interfaces of graphene with Ru(0001) and Ir(111) were modified using intercalation of a thin Mn layer and investigated by means of scanning tunnelling microscopy (STM) accompanied by density functional theory (DFT) calculations, which reproduce the observed experimental data. It is found that Mn forms a pseudomorphic layer on Ru(0001) under a strongly buckled graphene layer. In case of Mn intercalation in graphene/Ir(111), a buried thin layer of MnIr alloy is formed beneath the first Ir layer under a flat graphene layer. This unexpected observation is explained on the basis of phase diagram pictures for the Mn-Ru and Mn-Ir systems as well as via comparison of calculated total energies for the respective interfaces. Our results shed light on the understanding of mechanisms of the alloys formation at the graphene-metal interfaces and demonstrate their potential for the preparation of tailored interfaces for future graphene-based applications.