Effects of Vanadium Doping on the Optical Response and Electronic Structure of WS₂ Monolayers Article Swipe

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Materials science Monolayer Doping Vanadium Vanadium dioxide Optoelectronics Nanotechnology Thin film Metallurgy

Frederico B. Sousa , Boyang Zheng , Mingzu Liu , Geovani C. Resende , Da Zhou , M. A. Pimenta , Mauricio Terrones , Vincent H. Crespi , Leandro M. Malard ·

YOU? · · 2024 · Open Access · · DOI: https://doi.org/10.1002/adom.202400235 · OA: W4396614469

2D dilute magnetic semiconductors have been recently reported in transition metal dichalcogenides doped with spin‐polarized transition metal atoms, for example vanadium‐doped WS 2 monolayers, which exhibit room‐temperature ferromagnetic ordering. However, a broadband characterization of the electronic band structure of these doped WS 2 monolayers and its dependence on vanadium concentration is still lacking. Therefore, power‐dependent photoluminescence, resonant four‐wave mixing, and differential reflectance spectroscopies are performed here to study optical transitions close to the A exciton energy of vanadium‐doped WS 2 monolayers at three different doping levels. Instead of a single A exciton peak, vanadium‐doped samples exhibit two photoluminescence peaks associated with transitions from a donor‐like level and the conduction band minima. Moreover, resonant Raman and second‐harmonic generation experiments reveal a blueshift in the B exciton energy but no energy change in the C exciton after vanadium doping. Density functional theory calculations show that the band structure is sensitive to the Hubbard U correction for vanadium, and several scenarios are proposed to explain the two photoluminescence peaks around the A exciton energy region. This work provides the first broadband optical characterization of these 2D dilute magnetic semiconductors, shedding light on the novel and tunable electronic features of V‐doped WS 2 monolayers.