Project Details
Investigation of Two-Dimensional h-BCN Semiconductors
Applicant
Professor Dr. Axel Enders
Subject Area
Experimental Condensed Matter Physics
Term
from 2018 to 2024
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 412007813
This project is based on the hypothesis that the recently discovered 2D semiconductor h-BCN may replace graphene as a candidate material for 2D electronics. The 2D lattice structure of h-BN is identical to that of graphene, but with the graphenic sites occupied by atoms of boron, nitrogen and carbon. Hexagonal BCN exhibits a direct electronic band gap of 1.0 - 1.5 eV in preliminary measurements. However, the exact atomic structure of h-BCN is thus far unknown; computational modelling predicts that there are several possibilities to connect the precursor molecules, bis-BN cyclohexane, to form a covalent 2D layer after thermal dehydrogenation, which thus far have been indistinguishable in experimental studies. The goal of this project is to establish the materials-scientific basis of h-BCN. We will develop a fundamental understanding of the reaction kinetics during the h-BCN formation, the role of the supporting substrate during growth, the parameter space that determines the growth, local conductivities and the full k-space resolved electronic band structure. The experimental approach relies on state-of-the-art surface-scientific microscopy and spectroscopy methods under ultrahigh vacuum. The high risk and high reward component of this project are feasibility studies to exfoliate h-BCN from the substrate for prototype device fabrication. The suitability of h-BCN as nanotemplate for nanostructure growth will be explored. The impact of this study is expected to be huge, as the availability of graphene-like material with a moderate electronic bandgap, comparable to that of silicon and GaAs, could ultimately accelerate the development and implementation of 2D electronic devices.
DFG Programme
Research Grants
International Connection
Poland, USA
Cooperation Partners
Dr. James Hooper; Professor Shih-Yuan Liu, Ph.D.; Professorin Dr. Eva Zurek