2012
DOI: 10.1021/nn304315z
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Epitaxial Graphene on 4H-SiC(0001) Grown under Nitrogen Flux: Evidence of Low Nitrogen Doping and High Charge Transfer

Abstract: Nitrogen doping of graphene is of great interest for both fundamental research to explore the effect of dopants on a 2D electrical conductor and applications such as lithium storage, composites, and nanoelectronic devices. Here, we report on the modifications of the electronic properties of epitaxial graphene thanks to the introduction, during the growth, of nitrogen-atom substitution in the carbon honeycomb lattice. High-resolution transmission microscopy and low-energy electron microscopy investigations indi… Show more

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Cited by 104 publications
(107 citation statements)
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“…Only two components are present on the spectra [11] due to the bilayer graphene (G peak at binding energy BE ¼ 284.3 eV) and the SiC substrate (BE ¼ 282.6 eV). Respect to an as grown n-doped monolayer epitaxial graphene [18] the G peak presents a shift of about 0.4 eV to lower BE indicating a change in the doping, from n to p, induced by the hydrogenation process [11]. Moreover, the SiC component is shifted of about 1 eV to lower BE, which confirms that the hydrogen bonds are present at the SiC surface inducing this band bending variation [10] confirming a complete decoupling of the buffer layer.…”
Section: Resultsmentioning
confidence: 75%
“…Only two components are present on the spectra [11] due to the bilayer graphene (G peak at binding energy BE ¼ 284.3 eV) and the SiC substrate (BE ¼ 282.6 eV). Respect to an as grown n-doped monolayer epitaxial graphene [18] the G peak presents a shift of about 0.4 eV to lower BE indicating a change in the doping, from n to p, induced by the hydrogenation process [11]. Moreover, the SiC component is shifted of about 1 eV to lower BE, which confirms that the hydrogen bonds are present at the SiC surface inducing this band bending variation [10] confirming a complete decoupling of the buffer layer.…”
Section: Resultsmentioning
confidence: 75%
“…The p-type graphene is obtained by hydrogenation of epitaxial graphene resulting from the high temperature baking of a SiC substrate 27,28 . The latter presents several advantages, in particular the lack of a transfer step between the growth and the device design.…”
Section: Resultsmentioning
confidence: 99%
“…While doping graphene by adsorbates or more elaborate chemical means has made rapid progress, [1][2][3][4][5][6][7] opening a band-gap in graphene has been problematic. Two routes to wide-band-gap semiconducting graphene have been pioneered: electron confinement and chemical functionalization.…”
mentioning
confidence: 99%