Salvatore Cianci scite author profile

The possibility of almost linear tuning of the band gap and of the electrical and optical properties in monolayers (MLs) of semiconducting transition metal dichalcogenide (S-TMD) alloys opens up the way to fabricate materials with on-demand characteristics. By making use of photoluminescence spectroscopy, we investigate optical properties of WSSe MLs with a S/Se ratio of 57/43 deposited on SiO$_2$/Si substrate and encapsulated in hexagonal BN flakes. Similarly to the "parent" WS2 and WSe2 MLs, we assign the WSSe MLs to the ML family with the dark ground exciton state. We find that, in addition to the neutral bright A exciton line, three observed emission lines are associated with negatively charged excitons. The application of in-plane and out-of-plane magnetic fields allows us to assign undeniably the bright and dark (spin- and momentum-forbidden) negative trions as well as the phonon replica of the dark spin-forbidden complex. Furthermore, the existence of the single photon emitters in the WSSe ML is also demonstrated, thus prompting the opportunity to enlarge the wavelength range for potential future quantum applications of S-TMDs.

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Spatially Controlled Single Photon Emitters in hBN‐Capped WS₂ Domes

Cianci

Blundo

Tuzi

et al. 2023

Advanced Optical Materials

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Monolayers (MLs) of transition-metal dichalcogenides host efficient single-photon emitters (SPEs) usually associated to the presence of nanoscale mechanical deformations or strain. Large-scale spatial control of strain would enhance the scalability of such SPEs and allow for their incorporation into photonic structures. Here, the formation of regular arrays of strained hydrogen-filled one-layer-thick micro-domes obtained by H-ion irradiation and lithography-based approaches is reported. Typically, the H 2 liquefaction for temperatures T<32 K causes the disappearance of the domes preventing their use as potential SPEs. Here, it is shown that the dome deflation can be overcome by hBN heterostructuring, that is by depositing thin hBN flakes on the domes. This leads to the preservation of the dome structure at all temperatures, as found by micro-Raman and micro-photoluminescence (μ-PL) studies. Eventually, spatially controlled hBN-capped WS 2 domes show the appearance, at 5 K, of intense emission lines originating from localized excitons, which are shown to behave as quantum emitters here. The electronic properties of the emitters are addressed by time-resolved μ-PL yielding time decays of 1-10 ns, and by magneto-μ-PL measurements. The latter provide an exciton magnetic moment a factor of two larger than the value observed in planar strain-free MLs.

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Excitons and trions in WSSe monolayers

Olkowska‐Pucko¹,

Blundo²,

Zawadzka³

et al. 2022

Preprint

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