Probing charge transfer between molecular semiconductors and graphene

Research output: Contribution to journalArticleResearchpeer-review

Standard

Probing charge transfer between molecular semiconductors and graphene. / Matkovic, Aleksandar; Kratzer, Markus; Kaufmann, Benjamin et al.
In: Scientific reports (London : Nature Publishing Group), Vol. 7.2017, 9544, 25.08.2017.

Research output: Contribution to journalArticleResearchpeer-review

Harvard

Matkovic, A, Kratzer, M, Kaufmann, B, Vujin, J, Gajić, R & Teichert, C 2017, 'Probing charge transfer between molecular semiconductors and graphene', Scientific reports (London : Nature Publishing Group), vol. 7.2017, 9544. https://doi.org/10.1038/s41598-017-09419-3

APA

Matkovic, A., Kratzer, M., Kaufmann, B., Vujin, J., Gajić, R., & Teichert, C. (2017). Probing charge transfer between molecular semiconductors and graphene. Scientific reports (London : Nature Publishing Group), 7.2017, Article 9544. https://doi.org/10.1038/s41598-017-09419-3

Vancouver

Matkovic A, Kratzer M, Kaufmann B, Vujin J, Gajić R, Teichert C. Probing charge transfer between molecular semiconductors and graphene. Scientific reports (London : Nature Publishing Group). 2017 Aug 25;7.2017:9544. doi: 10.1038/s41598-017-09419-3

Author

Matkovic, Aleksandar ; Kratzer, Markus ; Kaufmann, Benjamin et al. / Probing charge transfer between molecular semiconductors and graphene. In: Scientific reports (London : Nature Publishing Group). 2017 ; Vol. 7.2017.

Bibtex - Download

@article{78a0b21abf154977a998608f3cc102ce,
title = "Probing charge transfer between molecular semiconductors and graphene",
abstract = "The unique density of states and exceptionally low electrical noise allow graphene-based field effect devices to be utilized as extremely sensitive potentiometers for probing charge transfer with adsorbed species. On the other hand, molecular level alignment at the interface with electrodes can strongly influence the performance of organic-based devices. For this reason, interfacial band engineering is crucial for potential applications of graphene/organic semiconductor heterostructures. Here, we demonstrate charge transfer between graphene and two molecular semiconductors, parahexaphenyl and buckminsterfullerene C60. Through in-situ measurements, we directly probe the charge transfer as the interfacial dipoles are formed. It is found that the adsorbed molecules do not affect electron scattering rates in graphene, indicating that charge transfer is the main mechanism governing the level alignment. From the amount of transferred charge and the molecular coverage of the grown films, the amount of charge transferred per adsorbed molecule is estimated, indicating very weak interaction.",
keywords = "graphene, organic semiconductors, charge transfer",
author = "Aleksandar Matkovic and Markus Kratzer and Benjamin Kaufmann and Jasna Vujin and Rados Gaji{\'c} and Christian Teichert",
year = "2017",
month = aug,
day = "25",
doi = "10.1038/s41598-017-09419-3",
language = "English",
volume = "7.2017",
journal = "Scientific reports (London : Nature Publishing Group)",
issn = "2045-2322",
publisher = "Nature Publishing Group",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Probing charge transfer between molecular semiconductors and graphene

AU - Matkovic, Aleksandar

AU - Kratzer, Markus

AU - Kaufmann, Benjamin

AU - Vujin, Jasna

AU - Gajić, Rados

AU - Teichert, Christian

PY - 2017/8/25

Y1 - 2017/8/25

N2 - The unique density of states and exceptionally low electrical noise allow graphene-based field effect devices to be utilized as extremely sensitive potentiometers for probing charge transfer with adsorbed species. On the other hand, molecular level alignment at the interface with electrodes can strongly influence the performance of organic-based devices. For this reason, interfacial band engineering is crucial for potential applications of graphene/organic semiconductor heterostructures. Here, we demonstrate charge transfer between graphene and two molecular semiconductors, parahexaphenyl and buckminsterfullerene C60. Through in-situ measurements, we directly probe the charge transfer as the interfacial dipoles are formed. It is found that the adsorbed molecules do not affect electron scattering rates in graphene, indicating that charge transfer is the main mechanism governing the level alignment. From the amount of transferred charge and the molecular coverage of the grown films, the amount of charge transferred per adsorbed molecule is estimated, indicating very weak interaction.

AB - The unique density of states and exceptionally low electrical noise allow graphene-based field effect devices to be utilized as extremely sensitive potentiometers for probing charge transfer with adsorbed species. On the other hand, molecular level alignment at the interface with electrodes can strongly influence the performance of organic-based devices. For this reason, interfacial band engineering is crucial for potential applications of graphene/organic semiconductor heterostructures. Here, we demonstrate charge transfer between graphene and two molecular semiconductors, parahexaphenyl and buckminsterfullerene C60. Through in-situ measurements, we directly probe the charge transfer as the interfacial dipoles are formed. It is found that the adsorbed molecules do not affect electron scattering rates in graphene, indicating that charge transfer is the main mechanism governing the level alignment. From the amount of transferred charge and the molecular coverage of the grown films, the amount of charge transferred per adsorbed molecule is estimated, indicating very weak interaction.

KW - graphene

KW - organic semiconductors

KW - charge transfer

U2 - 10.1038/s41598-017-09419-3

DO - 10.1038/s41598-017-09419-3

M3 - Article

VL - 7.2017

JO - Scientific reports (London : Nature Publishing Group)

JF - Scientific reports (London : Nature Publishing Group)

SN - 2045-2322

M1 - 9544

ER -

View graph of relations

SFX

Publication SFX

By the same authors

View more