Electronic and transport properties of unbalanced sublattice N-doping in graphene

Aurélien Lherbier; Andrés Rafael Botello-Méndez; Jean Christophe Charlier

doi:10.1021/nl304351z

Electronic and transport properties of unbalanced sublattice N-doping in graphene

Aurélien Lherbier^*, Andrés Rafael Botello-Méndez, Jean Christophe Charlier

^*Corresponding author for this work

Research output: Contribution to journal › Letter › Academic › peer-review

Abstract

Using both first-principles techniques and a real-space Kubo-Greenwood approach, electronic and transport properties of nitrogen-doped graphene with a single sublattice preference are investigated. Such a breaking of the sublattice symmetry leads to the appearance of a true band gap in graphene electronic spectrum even for a random distribution of the N dopants. More surprisingly, a natural spatial separation of both types of charge carriers at the band edge is predicted, leading to a highly asymmetric electronic transport. Both the presence of a band gap, allowing large on/off ratio, and an asymmetric transport pave a new route toward efficient graphene-based field-effect transistors.

Original language	English
Pages (from-to)	1446-1450
Number of pages	5
Journal	Nano Letters
Volume	13
Issue number	4
DOIs	https://doi.org/10.1021/nl304351z
Publication status	Published - 10 Apr 2013
Externally published	Yes

Keywords

ab initio
band gap
electronic transport
Graphene FET
nitrogen doping
tight-binding

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10.1021/nl304351z

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abstract = "Using both first-principles techniques and a real-space Kubo-Greenwood approach, electronic and transport properties of nitrogen-doped graphene with a single sublattice preference are investigated. Such a breaking of the sublattice symmetry leads to the appearance of a true band gap in graphene electronic spectrum even for a random distribution of the N dopants. More surprisingly, a natural spatial separation of both types of charge carriers at the band edge is predicted, leading to a highly asymmetric electronic transport. Both the presence of a band gap, allowing large on/off ratio, and an asymmetric transport pave a new route toward efficient graphene-based field-effect transistors.",

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T1 - Electronic and transport properties of unbalanced sublattice N-doping in graphene

AU - Lherbier, Aurélien

AU - Botello-Méndez, Andrés Rafael

AU - Charlier, Jean Christophe

PY - 2013/4/10

Y1 - 2013/4/10

N2 - Using both first-principles techniques and a real-space Kubo-Greenwood approach, electronic and transport properties of nitrogen-doped graphene with a single sublattice preference are investigated. Such a breaking of the sublattice symmetry leads to the appearance of a true band gap in graphene electronic spectrum even for a random distribution of the N dopants. More surprisingly, a natural spatial separation of both types of charge carriers at the band edge is predicted, leading to a highly asymmetric electronic transport. Both the presence of a band gap, allowing large on/off ratio, and an asymmetric transport pave a new route toward efficient graphene-based field-effect transistors.

AB - Using both first-principles techniques and a real-space Kubo-Greenwood approach, electronic and transport properties of nitrogen-doped graphene with a single sublattice preference are investigated. Such a breaking of the sublattice symmetry leads to the appearance of a true band gap in graphene electronic spectrum even for a random distribution of the N dopants. More surprisingly, a natural spatial separation of both types of charge carriers at the band edge is predicted, leading to a highly asymmetric electronic transport. Both the presence of a band gap, allowing large on/off ratio, and an asymmetric transport pave a new route toward efficient graphene-based field-effect transistors.

KW - ab initio

KW - band gap

KW - electronic transport

KW - Graphene FET

KW - nitrogen doping

KW - tight-binding

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SP - 1446

EP - 1450

JO - Nano Letters

JF - Nano Letters

IS - 4

ER -

Electronic and transport properties of unbalanced sublattice N-doping in graphene

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Keywords

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