Suppression of electron-vibron coupling in graphene nanoribbons contacted via a single atom

Joost van der Lit; Mark P. Boneschanscher; Daniel Vanmaekelbergh; Mari Ijas; Andreas Uppstu; Mikko Ervasti; Ari Harju; Peter Liljeroth; Ingmar Swart

doi:10.1038/ncomms3023

Suppression of electron-vibron coupling in graphene nanoribbons contacted via a single atom

Joost van der Lit, Mark P. Boneschanscher, Daniel Vanmaekelbergh, Mari Ijas, Andreas Uppstu, Mikko Ervasti, Ari Harju, Peter Liljeroth^*, Ingmar Swart

^*Corresponding author for this work

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

Abstract

Graphene nanostructures, where quantum confinement opens an energy gap in the band structure, hold promise for future electronic devices. To realize the full potential of these materials, atomic-scale control over the contacts to graphene and the graphene nanostructure forming the active part of the device is required. The contacts should have a high transmission and yet not modify the electronic properties of the active region significantly to maintain the potentially exciting physics offered by the nanoscale honeycomb lattice. Here we show how contacting an atomically well-defined graphene nanoribbon to a metallic lead by a chemical bond via only one atom significantly influences the charge transport through the graphene nanoribbon but does not affect its electronic structure. Specifically, we find that creating well-defined contacts can suppress inelastic transport channels.

Original language	English
Article number	2023
Number of pages	6
Journal	Nature Communications [E]
Volume	4
DOIs	https://doi.org/10.1038/ncomms3023
Publication status	Published - Jun 2013

Funding

The authors acknowledge useful discussions with Gerhard Meyer and Harold de Wijn. We are grateful to Bert Klein Gebbink for providing organic synthesis facilities. This research was supported by the NWO (Chemical Sciences, Veni-grant 722.011.007), Academy of Finland (the Centre of Excellence programmes No. 250280 and No. 251748), the European Research Council (ERC-2011-StG 278698-PRECISE-NANO) and FOM ('Control over Functional Nanoparticle Solids (FNPS)'). We acknowledge the computational resources provided by Aalto Science-IT project and Finland's IT Centre for Science (CSC).

Keywords

EPITAXIAL GRAPHENE
MOLECULE CHEMISTRY
SPECTROSCOPY
CONDUCTANCE
MICROSCOPY
SCATTERING
TRANSPORT
JUNCTIONS
BENZENE
SURFACE

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10.1038/ncomms3023

Cite this

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title = "Suppression of electron-vibron coupling in graphene nanoribbons contacted via a single atom",

abstract = "Graphene nanostructures, where quantum confinement opens an energy gap in the band structure, hold promise for future electronic devices. To realize the full potential of these materials, atomic-scale control over the contacts to graphene and the graphene nanostructure forming the active part of the device is required. The contacts should have a high transmission and yet not modify the electronic properties of the active region significantly to maintain the potentially exciting physics offered by the nanoscale honeycomb lattice. Here we show how contacting an atomically well-defined graphene nanoribbon to a metallic lead by a chemical bond via only one atom significantly influences the charge transport through the graphene nanoribbon but does not affect its electronic structure. Specifically, we find that creating well-defined contacts can suppress inelastic transport channels.",

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year = "2013",

month = jun,

doi = "10.1038/ncomms3023",

language = "English",

volume = "4",

journal = "Nature Communications [E]",

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AU - van der Lit, Joost

AU - Boneschanscher, Mark P.

AU - Vanmaekelbergh, Daniel

AU - Ijas, Mari

AU - Uppstu, Andreas

AU - Ervasti, Mikko

AU - Harju, Ari

AU - Liljeroth, Peter

AU - Swart, Ingmar

PY - 2013/6

Y1 - 2013/6

N2 - Graphene nanostructures, where quantum confinement opens an energy gap in the band structure, hold promise for future electronic devices. To realize the full potential of these materials, atomic-scale control over the contacts to graphene and the graphene nanostructure forming the active part of the device is required. The contacts should have a high transmission and yet not modify the electronic properties of the active region significantly to maintain the potentially exciting physics offered by the nanoscale honeycomb lattice. Here we show how contacting an atomically well-defined graphene nanoribbon to a metallic lead by a chemical bond via only one atom significantly influences the charge transport through the graphene nanoribbon but does not affect its electronic structure. Specifically, we find that creating well-defined contacts can suppress inelastic transport channels.

AB - Graphene nanostructures, where quantum confinement opens an energy gap in the band structure, hold promise for future electronic devices. To realize the full potential of these materials, atomic-scale control over the contacts to graphene and the graphene nanostructure forming the active part of the device is required. The contacts should have a high transmission and yet not modify the electronic properties of the active region significantly to maintain the potentially exciting physics offered by the nanoscale honeycomb lattice. Here we show how contacting an atomically well-defined graphene nanoribbon to a metallic lead by a chemical bond via only one atom significantly influences the charge transport through the graphene nanoribbon but does not affect its electronic structure. Specifically, we find that creating well-defined contacts can suppress inelastic transport channels.

KW - EPITAXIAL GRAPHENE

KW - MOLECULE CHEMISTRY

KW - SPECTROSCOPY

KW - CONDUCTANCE

KW - MICROSCOPY

KW - SCATTERING

KW - TRANSPORT

KW - JUNCTIONS

KW - BENZENE

KW - SURFACE

U2 - 10.1038/ncomms3023

DO - 10.1038/ncomms3023

M3 - Article

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JO - Nature Communications [E]

JF - Nature Communications [E]

M1 - 2023

ER -

Suppression of electron-vibron coupling in graphene nanoribbons contacted via a single atom

Abstract

Funding

Keywords

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