| Literature DB >> 28437062 |
Claudia Ojeda-Aristizabal1,2,3,4, Elton J G Santos5,6,7, Seita Onishi1,2,3, Aiming Yan1,2,3, Haider I Rasool1,2,3, Salman Kahn1, Yinchuan Lv1, Drew W Latzke2,8, Jairo Velasco1, Michael F Crommie1,2,3, Matthew Sorensen1, Kenneth Gotlieb2,8, Chiu-Yun Lin2, Kenji Watanabe9, Takashi Taniguchi9, Alessandra Lanzara1,2, Alex Zettl1,2,3.
Abstract
Charge transfer at the interface between dissimilar materials is at the heart of electronics and photovoltaics. Here we study the molecular orientation, electronic structure, and local charge transfer at the interface region of C60 deposited on graphene, with and without supporting substrates such as hexagonal boron nitride. We employ ab initio density functional theory with van der Waals interactions and experimentally characterize interface devices using high-resolution transmission electron microscopy and electronic transport. Charge transfer between C60 and the graphene is found to be sensitive to the nature of the underlying supporting substrate and to the crystallinity and local orientation of the C60. Even at room temperature, C60 molecules interfaced to graphene are orientationally locked into position. High electron and hole mobilities are preserved in graphene with crystalline C60 overlayers, which has ramifications for organic high-mobility field-effect devices.Entities:
Keywords: C60; fullerenes; graphene; interfacial charge transfer; organic semiconducting molecules
Year: 2017 PMID: 28437062 DOI: 10.1021/acsnano.7b00551
Source DB: PubMed Journal: ACS Nano ISSN: 1936-0851 Impact factor: 15.881