Hydrogen-mediated CVD epitaxy of Graphene on SiC: growth mechanism and atomic configuration

TL;DR

This study elucidates the hydrogen-assisted CVD growth mechanism of graphene on SiC, revealing a two-stage process involving nucleation and hydrogen desorption, and introduces a method to control graphene domain types for nanoelectronic applications.

Contribution

It uncovers the detailed growth mechanism of graphene on SiC under hydrogen flow and presents a quantitative analysis method for domain proportions, enabling better control of graphene epitaxy.

Findings

Identified two growth stages: nucleation and hydrogen desorption.

Quantified domain proportions using XPS analysis.

Demonstrated control over graphene domain types via H2 flow rate.

Abstract

Despite the large literature focused on the growth of graphene (Gr) on 6H-SiC(0001) by chemical vapour deposition (CVD), some important issues have not been solved and full wafer scale epitaxy of Gr remains challenging, hampering applications in microelectronics. With this study we shed light on the generic mechanism which produces the coexistence of two different types of Gr domains, whose proportion can be carefully controlled by tuning the H2 flow rate. For the first time, we show that the growth of Gr using CVD under H2/Ar flow rate proceeds in two stages. Firstly, the nucleation of free-standing epitaxial graphene on hydrogen (H-Gr) occurs, then H-atoms eventually desorb from either step edges or defects. This gives rise, for H2 flow rate below a critical value, to the formation of (6x6)Gr domains on 6H-SiC(0001). The front of H-desorption progresses proportionally to the reduction of H2. Using a robust and generic X-ray photoelectron spectroscopy (XPS) analysis, we realistically quantify the proportions of H-Gr and (6x6)Gr domains of a Gr film synthetized in any experimental conditions. Scanning tunnelling microscopy supports the XPS measurements. From these results we can deduce that the H- assisted CVD growth of Gr developed here is a unique method to grow fully free-standing H-Gr on the contrary to the method consisting of H-intercalation below epitaxial Gr on buffer layer. These results are of crucial importance for future applications of Gr/SiC(0001) in nanoelectronics, providing the groundwork for the use of Gr as an optimal template layer for Van der Waals homo- and hetero-epitaxy.