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The opto‐electronic properties of semiconducting 2D materials can be flexibly manipulated by engineering the atomic‐scale environment. This can be done by including 2D materials in tailored van der Waals (vdW) stacks, whose optical response is a function of the number and the type of adjacent 2D layers. This work reports a systematic investigation of the dielectric function of 2D semiconducting WS2 in various stacking configurations: monolayer, 3R/2H homobilayer, and WS2/MoS2 heterobilayer. Reliable, Kramers–Kronig‐consistent dielectric functions are obtained for WS2 in each configuration by means of spectroscopic ellipsometry (SE) and related parametric optical modeling in a wide spectral range (1.55–3.10 eV). The results of SE are combined with photoluminescence and absorbance spectra to identify the spectral position of the main excitonic features in WS2, which manifest sizable redshifts depending on the stacking configuration. These results represent a consistent reference set for the dielectric function of WS2 in vdW stacking configurations of particular interest for the scientific and technological field, and can be fruitfully exploited for reliable predictions of the optical response of WS2‐containing systems.

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Local dielectric function of hBN-encapsulated WS₂ flakes grown by chemical vapor deposition

Ferrera

Sharma²,

Milekhin³

et al. 2023

J. Phys.: Condens. Matter

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Hexagonal boron nitride (hBN), sometimes referred to as white graphene, receives growing interest in the scientific community, especially when combined into van der Waals homo- and heterostacks, in which novel and interesting phenomena may arise. hBN is also commonly used in combination with 2D semiconducting transition metal dichalcogenides (TMDCs). The realization of hBN-encapsulated TMDC homo- and heterostacks can indeed offer opportunities to investigate and compare TMDC excitonic properties in various stacking configurations. In this work, we investigate the optical response at the micrometric scale of mono- and homo-bilayer WS2 grown by chemical vapor deposition and encapsulated between two single layers of hBN. Imaging spectroscopic ellipsometry (ISE) is exploited to extract the local dielectric functions across one single WS2 flake and detect the evolution of excitonic spectral features from monolayer to bilayer regions. Exciton energies undergo a redshift by passing from hBN-encapsulated single layer to homo-bilayer WS2, as also confirmed by photoluminescence spectra. Our results can provide a reference for the study of the dielectric properties of more complex systems where hBN is combined with other 2D van der Waals materials into heterostructures and are stimulating towards the investigation of the optical response of other technologically-relevant heterostacks.

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Ermes Peci

Dielectric Function of 2D Tungsten Disulfide in Homo‐ and Heterobilayer Stacking

Local dielectric function of hBN-encapsulated WS₂ flakes grown by chemical vapor deposition

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Ermes Peci

Dielectric Function of 2D Tungsten Disulfide in Homo‐ and Heterobilayer Stacking

Local dielectric function of hBN-encapsulated WS2 flakes grown by chemical vapor deposition

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Local dielectric function of hBN-encapsulated WS₂ flakes grown by chemical vapor deposition