Electronic and Chemical Properties of Donor, Acceptor Centers in Graphene
Abstract
Chemical doping is one of the most suitable ways of tuning the electronic properties of graphene and a promising candidate for a band gap opening. In this work we report a reliable and tunable method for preparation of high-quality boron and nitrogen co-doped graphene on silicon carbide substrate. We combine experimental (dAFM, STM, XPS, NEXAFS) and theoretical (total energy DFT and simulated STM) studies to analyze the structural, chemical, and electronic properties of the single-atom substitutional dopants in graphene. We show that chemical identification of boron and nitrogen substitutional defects can be achieved in the STM channel due to the quantum interference effect, arising due to the specific electronic structure of nitrogen dopant sites. Chemical reactivity of single boron and nitrogen dopants is analyzed using force–distance spectroscopy by means of dAFM- Text
- Journal contribution
- Biophysics
- Biochemistry
- Pharmacology
- Sociology
- Developmental Biology
- Environmental Sciences not elsewhere classified
- Chemical Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- Information Systems not elsewhere classified
- energy DFT
- graphene
- nitrogen substitutional defects
- XPS
- Chemical Properties
- Acceptor Centers
- nitrogen dopant sites
- chemical reactivity
- dAFM
- silicon carbide substrate
- boron
- STM channel
- chemical identification
- tunable method
- NEXAFS
- quantum interference effect
- nitrogen dopants
- band gap opening
- GrapheneChemical doping
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This paper was published in FigShare.
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