High-Mobility and High-Optical Quality Atomically Thin WS 2

Reale, Francesco; Palczynski, Pawel; Amit, Iddo; Jones, Gareth F; Mehew, Jake D; Bacon, Agnes; Ni, Na; Sherrell, Peter C; Agnoli, Stefano; Craciun, Monica F; others

doi:10.1038/s41598-017-14928-2

High-Mobility and High-Optical Quality Atomically Thin WS 2

Reale, Francesco; Palczynski, Pawel; Amit, Iddo; Jones, Gareth F; Mehew, Jake D; Bacon, Agnes; Ni, Na; Sherrell, Peter C; Agnoli, Stefano; Craciun, Monica F; others

Authors

Francesco Reale

Pawel Palczynski

Dr Iddo Amit iddo.amit@durham.ac.uk
Assistant Professor

Gareth F Jones

Jake D Mehew

Agnes Bacon

Na Ni

Peter C Sherrell

Stefano Agnoli

Monica F Craciun

others

Abstract

The rise of atomically thin materials has the potential to enable a paradigm shift in modern technologies by introducing multi-functional materials in the semiconductor industry. To date the growth of high quality atomically thin semiconductors (e.g. WS2) is one of the most pressing challenges to unleash the potential of these materials and the growth of mono- or bi-layers with high crystal quality is yet to see its full realization. Here, we show that the novel use of molecular precursors in the controlled synthesis of mono- and bi-layer WS2 leads to superior material quality compared to the widely used direct sulfidization of WO3-based precursors. Record high room temperature charge carrier mobility up to 52 cm2/Vs and ultra-sharp photoluminescence linewidth of just 36 meV over submillimeter areas demonstrate that the quality of this material supersedes also that of naturally occurring materials. By exploiting surface diffusion kinetics of W and S species adsorbed onto a substrate, a deterministic layer thickness control has also been achieved promoting the design of scalable synthesis routes.

Citation

Reale, F., Palczynski, P., Amit, I., Jones, G. F., Mehew, J. D., Bacon, A., …others. (2017). High-Mobility and High-Optical Quality Atomically Thin WS 2. Scientific Reports, 7(1), Article 14911. https://doi.org/10.1038/s41598-017-14928-2

Journal Article Type	Article
Acceptance Date	Oct 19, 2017
Online Publication Date	Nov 2, 2017
Publication Date	Nov 2, 2017
Deposit Date	Jul 5, 2018
Publicly Available Date	Jul 6, 2018
Journal	Scientific Reports
Publisher	Nature Research
Peer Reviewed	Peer Reviewed
Volume	7
Issue	1
Article Number	14911
DOI	https://doi.org/10.1038/s41598-017-14928-2

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