George W. Flynn scite author profile

Using micro-Raman spectroscopy and scanning tunneling microscopy, we study the relationship between structural distortion and electrical hole doping of graphene on a silicon dioxide substrate. The observed upshift of the Raman G band represents charge doping and not compressive strain. Two independent factors control the doping: (1) the degree of graphene coupling to the substrate and (2) exposure to oxygen and moisture. Thermal annealing induces a pronounced structural distortion due to close coupling to SiO2 and activates the ability of diatomic oxygen to accept charge from graphene. Gas flow experiments show that dry oxygen reversibly dopes graphene; doping becomes stronger and more irreversible in the presence of moisture and over long periods of time. We propose that oxygen molecular anions are stabilized by water solvation and electrostatic binding to the silicon dioxide surface.

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Graphene Oxidation: Thickness-Dependent Etching and Strong Chemical Doping

Liu

et al. 2008

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Patterned graphene shows substantial potential for applications in future molecular-scale integrated electronics. Environmental effects are a critical issue in a single-layer material where every atom is on the surface. Especially intriguing is the variety of rich chemical interactions shown by molecular oxygen with aromatic molecules. We find that O 2 etching kinetics vary strongly with the number of graphene layers in the sample. Three-layer-thick samples show etching similar to bulk natural graphite. Single-layer graphene reacts faster and shows random etch pits in contrast to natural graphite where nucleation occurs at point defects. In addition, basal plane oxygen species strongly hole dope graphene, with a Fermi level shift of approximately 0.5 eV. These oxygen species desorb partially in an Ar gas flow, or under irradiation by far UV light, and readsorb again in an O 2 atmosphere at room temperature. This strongly doped graphene is very different from "graphene oxide" made by mineral acid attack.

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Visualizing Individual Nitrogen Dopants in Monolayer Graphene

Zhao

Rim

et al. 2011

Science

803

744

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In monolayer graphene, substitutional doping during growth can be used to alter its electronic properties. We used scanning tunneling microscopy, Raman spectroscopy, x-ray spectroscopy, and first principles calculations to characterize individual nitrogen dopants in monolayer graphene grown on a copper substrate. Individual nitrogen atoms were incorporated as graphitic dopants, and a fraction of the extra electron on each nitrogen atom was delocalized into the graphene lattice. The electronic structure of nitrogen-doped graphene was strongly modified only within a few lattice spacings of the site of the nitrogen dopant. These findings show that chemical doping is a promising route to achieving high-quality graphene films with a large carrier concentration.

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Ultraflat graphene

Lui

Liu

Mak

et al. 2009

Nature

661

499

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George W. Flynn

Atmospheric Oxygen Binding and Hole Doping in Deformed Graphene on a SiO₂ Substrate

Graphene Oxidation: Thickness-Dependent Etching and Strong Chemical Doping

Visualizing Individual Nitrogen Dopants in Monolayer Graphene

Ultraflat graphene

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About

George W. Flynn

Atmospheric Oxygen Binding and Hole Doping in Deformed Graphene on a SiO2 Substrate

Graphene Oxidation: Thickness-Dependent Etching and Strong Chemical Doping

Visualizing Individual Nitrogen Dopants in Monolayer Graphene

Ultraflat graphene

Contact Info

Product

Resources

About

Atmospheric Oxygen Binding and Hole Doping in Deformed Graphene on a SiO₂ Substrate