Emergence of photoswitchable states in a graphene-azobenzene-au platform

Emanuela Margapoti; Philipp Strobel; Mahmoud M. Asmar; Max Seifert; Juan Li; Matthias Sachsenhauser; Özlem Ceylan; Carlos Andres Palma; Johannes V. Barth; Jose A. Garrido; Anna Cattani-Scholz; Sergio E. Ulloa; Jonathan J. Finley

doi:10.1021/nl503681z

Emergence of photoswitchable states in a graphene-azobenzene-au platform

Emanuela Margapoti^*, Philipp Strobel, Mahmoud M. Asmar, Max Seifert, Juan Li, Matthias Sachsenhauser, Özlem Ceylan, Carlos Andres Palma, Johannes V. Barth, Jose A. Garrido, Anna Cattani-Scholz, Sergio E. Ulloa, Jonathan J. Finley

^*Corresponding author for this work

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

43 Citations (Scopus)

Abstract

The perfect transmission of charge carriers through potential barriers in graphene (Klein tunneling) is a direct consequence of the Dirac equation that governs the low-energy carrier dynamics. As a result, localized states do not exist in unpatterned graphene, but quasibound states can occur for potentials with closed integrable dynamics. Here, we report the observation of resonance states in photoswitchable self-assembled molecular(SAM)-graphene hybrid. Conductive AFM measurements performed at room temperature reveal strong current resonances, the strength of which can be reversibly gated on- and off- by optically switching the molecular conformation of the mSAM. Comparisons of the voltage separation between current resonances (∼70-120 mV) with solutions of the Dirac equation indicate that the radius of the gating potential is ∼7 ± 2 nm with a strength ≥0.5 eV. Our results and methods might provide a route toward optically programmable carrier dynamics and transport in graphene nanomaterials.

Original language	English
Pages (from-to)	6823-6827
Number of pages	5
Journal	Nano Letters
Volume	14
Issue number	12
DOIs	https://doi.org/10.1021/nl503681z
Publication status	Published - 10 Dec 2014
Externally published	Yes

Keywords

atomic microscopy
doping
graphene
photochromatic molecules

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10.1021/nl503681z

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@article{2643637205ae407f87ec1a641c67ab80,

title = "Emergence of photoswitchable states in a graphene-azobenzene-au platform",

abstract = "The perfect transmission of charge carriers through potential barriers in graphene (Klein tunneling) is a direct consequence of the Dirac equation that governs the low-energy carrier dynamics. As a result, localized states do not exist in unpatterned graphene, but quasibound states can occur for potentials with closed integrable dynamics. Here, we report the observation of resonance states in photoswitchable self-assembled molecular(SAM)-graphene hybrid. Conductive AFM measurements performed at room temperature reveal strong current resonances, the strength of which can be reversibly gated on- and off- by optically switching the molecular conformation of the mSAM. Comparisons of the voltage separation between current resonances (∼70-120 mV) with solutions of the Dirac equation indicate that the radius of the gating potential is ∼7 ± 2 nm with a strength ≥0.5 eV. Our results and methods might provide a route toward optically programmable carrier dynamics and transport in graphene nanomaterials.",

keywords = "atomic microscopy, doping, graphene, photochromatic molecules",

author = "Emanuela Margapoti and Philipp Strobel and Asmar, {Mahmoud M.} and Max Seifert and Juan Li and Matthias Sachsenhauser and {\"O}zlem Ceylan and Palma, {Carlos Andres} and Barth, {Johannes V.} and Garrido, {Jose A.} and Anna Cattani-Scholz and Ulloa, {Sergio E.} and Finley, {Jonathan J.}",

note = "Publisher Copyright: {\textcopyright} 2014 American Chemical Society.",

year = "2014",

month = dec,

day = "10",

doi = "10.1021/nl503681z",

language = "English",

volume = "14",

pages = "6823--6827",

journal = "Nano Letters",

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publisher = "American Chemical Society",

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T1 - Emergence of photoswitchable states in a graphene-azobenzene-au platform

AU - Margapoti, Emanuela

AU - Strobel, Philipp

AU - Asmar, Mahmoud M.

AU - Seifert, Max

AU - Li, Juan

AU - Sachsenhauser, Matthias

AU - Ceylan, Özlem

AU - Palma, Carlos Andres

AU - Barth, Johannes V.

AU - Garrido, Jose A.

AU - Cattani-Scholz, Anna

AU - Ulloa, Sergio E.

AU - Finley, Jonathan J.

PY - 2014/12/10

Y1 - 2014/12/10

N2 - The perfect transmission of charge carriers through potential barriers in graphene (Klein tunneling) is a direct consequence of the Dirac equation that governs the low-energy carrier dynamics. As a result, localized states do not exist in unpatterned graphene, but quasibound states can occur for potentials with closed integrable dynamics. Here, we report the observation of resonance states in photoswitchable self-assembled molecular(SAM)-graphene hybrid. Conductive AFM measurements performed at room temperature reveal strong current resonances, the strength of which can be reversibly gated on- and off- by optically switching the molecular conformation of the mSAM. Comparisons of the voltage separation between current resonances (∼70-120 mV) with solutions of the Dirac equation indicate that the radius of the gating potential is ∼7 ± 2 nm with a strength ≥0.5 eV. Our results and methods might provide a route toward optically programmable carrier dynamics and transport in graphene nanomaterials.

AB - The perfect transmission of charge carriers through potential barriers in graphene (Klein tunneling) is a direct consequence of the Dirac equation that governs the low-energy carrier dynamics. As a result, localized states do not exist in unpatterned graphene, but quasibound states can occur for potentials with closed integrable dynamics. Here, we report the observation of resonance states in photoswitchable self-assembled molecular(SAM)-graphene hybrid. Conductive AFM measurements performed at room temperature reveal strong current resonances, the strength of which can be reversibly gated on- and off- by optically switching the molecular conformation of the mSAM. Comparisons of the voltage separation between current resonances (∼70-120 mV) with solutions of the Dirac equation indicate that the radius of the gating potential is ∼7 ± 2 nm with a strength ≥0.5 eV. Our results and methods might provide a route toward optically programmable carrier dynamics and transport in graphene nanomaterials.

KW - atomic microscopy

KW - doping

KW - graphene

KW - photochromatic molecules

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U2 - 10.1021/nl503681z

DO - 10.1021/nl503681z

M3 - Article

AN - SCOPUS:84916608188

SN - 1530-6984

VL - 14

SP - 6823

EP - 6827

JO - Nano Letters

JF - Nano Letters

IS - 12

ER -

Emergence of photoswitchable states in a graphene-azobenzene-au platform

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Keywords

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