| Literature DB >> 26143940 |
Hyun-Cheol Kim1, Hakseong Kim1, Jae-Ung Lee2, Han-Byeol Lee1, Doo-Hua Choi1, Jun-Ho Lee1, Wi Hyoung Lee3, Sung Ho Jhang1, Bae Ho Park1, Hyeonsik Cheong2, Sang-Wook Lee1, Hyun-Jong Chung1.
Abstract
The optical constants, bandgaps, and band alignments of mono-, bi-, and trilayer WS2 were experimentally measured, and an extraordinarily high dependency on the number of layers was revealed. The refractive indices and extinction coefficients were extracted from the optical-contrast oscillation for various thicknesses of SiO2 on a Si substrate. The bandgaps of the few-layer WS2 were both optically and electrically measured, indicating high exciton-binding energies. The Schottky-barrier heights (SBHs) with Au/Cr contact were also extracted, depending on the number of layers (1-28). From an engineering viewpoint, the bandgap can be modulated from 3.49 to 2.71 eV with additional layers. The SBH can also be reduced from 0.37 eV for a monolayer to 0.17 eV for 28 layers. The technique of engineering materials' properties by modulating the number of layers opens pathways uniquely adaptable to transition-metal dichalcogenides.Entities:
Keywords: Schottky barrier; band-alignment; bandgap; transition-metal dichalcogenide; tungsten disulfide
Year: 2015 PMID: 26143940 DOI: 10.1021/acsnano.5b01727
Source DB: PubMed Journal: ACS Nano ISSN: 1936-0851 Impact factor: 15.881