Nanoscale reduction of graphene fluoride via thermochemical nanolithography

Woo Kyung Lee; Michael Haydell; Jeremy T. Robinson; Arnaldo R. Laracuente; Elena Cimpoiasu; William P. King; Paul E. Sheehan

doi:10.1021/nn4021746

Nanoscale reduction of graphene fluoride via thermochemical nanolithography

Woo Kyung Lee, Michael Haydell, Jeremy T. Robinson, Arnaldo R. Laracuente, Elena Cimpoiasu, William P. King, Paul E. Sheehan

Research output: Contribution to journal › Article › peer-review

Abstract

Graphene nanoribbons (GNRs) would be the ideal building blocks for all carbon electronics; however, many challenges remain in developing an appropriate nanolithography that generates high-quality ribbons in registry with other devices. Here we report direct and local fabrication of GNRs by thermochemical nanolithography, which uses a heated AFM probe to locally convert highly insulating graphene fluoride to conductive graphene. Chemically isolated GNRs as narrow as 40 nm show p-doping behavior and sheet resistances as low as 22.9 KΩ/□ in air, only approximately 10× higher than that of pristine graphene. The impact of probe temperature and speed are examined as well as the variable-temperature transport properties of the GNR.

Original language	English (US)
Pages (from-to)	6219-6224
Number of pages	6
Journal	ACS Nano
Volume	7
Issue number	7
DOIs	https://doi.org/10.1021/nn4021746
State	Published - Jul 23 2013

Keywords

atomic force microscopy
graphene fluoride
graphene nanoribbons
thermochemical nanolithography

ASJC Scopus subject areas

General Materials Science
General Engineering
General Physics and Astronomy

Online availability

10.1021/nn4021746

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abstract = "Graphene nanoribbons (GNRs) would be the ideal building blocks for all carbon electronics; however, many challenges remain in developing an appropriate nanolithography that generates high-quality ribbons in registry with other devices. Here we report direct and local fabrication of GNRs by thermochemical nanolithography, which uses a heated AFM probe to locally convert highly insulating graphene fluoride to conductive graphene. Chemically isolated GNRs as narrow as 40 nm show p-doping behavior and sheet resistances as low as 22.9 KΩ/□ in air, only approximately 10× higher than that of pristine graphene. The impact of probe temperature and speed are examined as well as the variable-temperature transport properties of the GNR.",

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AU - Lee, Woo Kyung

AU - Haydell, Michael

AU - Robinson, Jeremy T.

AU - Laracuente, Arnaldo R.

AU - Cimpoiasu, Elena

AU - King, William P.

AU - Sheehan, Paul E.

PY - 2013/7/23

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N2 - Graphene nanoribbons (GNRs) would be the ideal building blocks for all carbon electronics; however, many challenges remain in developing an appropriate nanolithography that generates high-quality ribbons in registry with other devices. Here we report direct and local fabrication of GNRs by thermochemical nanolithography, which uses a heated AFM probe to locally convert highly insulating graphene fluoride to conductive graphene. Chemically isolated GNRs as narrow as 40 nm show p-doping behavior and sheet resistances as low as 22.9 KΩ/□ in air, only approximately 10× higher than that of pristine graphene. The impact of probe temperature and speed are examined as well as the variable-temperature transport properties of the GNR.

AB - Graphene nanoribbons (GNRs) would be the ideal building blocks for all carbon electronics; however, many challenges remain in developing an appropriate nanolithography that generates high-quality ribbons in registry with other devices. Here we report direct and local fabrication of GNRs by thermochemical nanolithography, which uses a heated AFM probe to locally convert highly insulating graphene fluoride to conductive graphene. Chemically isolated GNRs as narrow as 40 nm show p-doping behavior and sheet resistances as low as 22.9 KΩ/□ in air, only approximately 10× higher than that of pristine graphene. The impact of probe temperature and speed are examined as well as the variable-temperature transport properties of the GNR.

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Nanoscale reduction of graphene fluoride via thermochemical nanolithography

Abstract

Keywords

ASJC Scopus subject areas

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