English

The graphene/n-Ge(110) interface: structure, doping, and electronic properties

Materials Science 2018-04-02 v1

Abstract

The implementation of graphene in semiconducting technology requires the precise knowledge about the graphene-semiconductor interface. In our work the structure and electronic properties of the graphene/nn-Ge(110) interface are investigated on the local (nm) and macro (from μm\mu\mathrm{m} to mm) scales via a combination of different microscopic and spectroscopic surface science techniques accompanied by density functional theory calculations. The electronic structure of freestanding graphene remains almost completely intact in this system, with only a moderate nn-doping indicating weak interaction between graphene and the Ge substrate. With regard to the optimization of graphene growth it is found that the substrate temperature is a crucial factor, which determines the graphene layer alignment on the Ge(110) substrate during its growth from the atomic carbon source. Moreover, our results demonstrate that the preparation routine for graphene on the doped semiconducting material (nn-Ge) leads to the effective segregation of dopants at the interface between graphene and Ge(110). Furthermore, it is shown that these dopant atoms might form regular structures at the graphene/Ge interface and induce the doping of graphene. Our findings help to understand the interface properties of the graphene-semiconductor interfaces and the effect of dopants on the electronic structure of graphene in such systems.

Keywords

Cite

@article{arxiv.1801.00549,
  title  = {The graphene/n-Ge(110) interface: structure, doping, and electronic properties},
  author = {Julia Tesch and Fabian Paschke and Mikhail Fonin and Marko Wietstruk and Stefan Böttcher and Roland J. Koch and Aaron Bostwick and Chris Jozwiak and Eli Rotenberg and Anna Makarova and Beate Paulus and Elena Voloshina and Yuriy Dedkov},
  journal= {arXiv preprint arXiv:1801.00549},
  year   = {2018}
}

Comments

submitted on 21.12.2017; manuscript and supplementary info

R2 v1 2026-06-22T23:34:05.020Z