Iris Niehues scite author profile

Semiconducting transition metal dichalcogenide (TMDC) monolayers have exceptional physical properties. They show bright photoluminescence due to their unique band structure and absorb more than 10% of the light at their excitonic resonances despite their atomic thickness. At room temperature, the width of the exciton transitions is governed by the exciton-phonon interaction leading to strongly asymmetric line shapes. TMDC monolayers are also extremely flexible, sustaining mechanical strain of about 10% without breaking. The excitonic properties strongly depend on strain. For example, exciton energies of TMDC monolayers significantly redshift under uniaxial tensile strain. Here, we demonstrate that the width and the asymmetric line shape of excitonic resonances in TMDC monolayers can be controlled with applied strain. We measure photoluminescence and absorption spectra of the A exciton in monolayer MoSe, WSe, WS, and MoS under uniaxial tensile strain. We find that the A exciton substantially narrows and becomes more symmetric for the selenium-based monolayer materials, while no change is observed for atomically thin WS. For MoS monolayers, the line width increases. These effects are due to a modified exciton-phonon coupling at increasing strain levels because of changes in the electronic band structure of the respective monolayer materials. This interpretation based on steady-state experiments is corroborated by time-resolved photoluminescence measurements. Our results demonstrate that moderate strain values on the order of only 1% are already sufficient to globally tune the exciton-phonon interaction in TMDC monolayers and hold the promise for controlling the coupling on the nanoscale.

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Reversible uniaxial strain tuning in atomically thin WSe ₂

Schmidt¹,

Niehues²,

Schneider³

et al. 2016

2D Mater.

148

164

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Due to their unique band structure, single layers of transition metal dichalcogenides are promising for new atomic-scale physics and devices. It has been shown that the band structure and the excitonic transitions can be tuned by straining the material. Recently, the discovery of single-photon emission from localized excitons has put monolayer WSe 2 in the spotlight. The localized light emitters might be related to local strain potentials in the monolayer. Here, we measure strain-dependent energy shifts for the A, B, C, and D excitons for uniaxial tensile strain up to 1.4% in monolayer WSe 2 by performing absorption measurements. A gauge factor of -54 , meV % -50 , meV % +17 , meV % and -22 meV % is derived for the A, B, C, and D exciton, respectively. These values are in good agreement with ab initio GW-BSE calculations. Furthermore, we examine the spatial strain distribution in the WSe 2 monolayer at different applied strain levels. We find that the size of the monolayer is crucial for an efficient transfer of strain from the substrate to the monolayer. RECEIVED

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Iris Niehues

Nanoscale Positioning of Single‐Photon Emitters in Atomically Thin WSe₂

Strain Control of Exciton–Phonon Coupling in Atomically Thin Semiconductors

Reversible uniaxial strain tuning in atomically thin WSe ₂

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Iris Niehues

Nanoscale Positioning of Single‐Photon Emitters in Atomically Thin WSe2

Strain Control of Exciton–Phonon Coupling in Atomically Thin Semiconductors

Reversible uniaxial strain tuning in atomically thin WSe 2

Contact Info

Product

Resources

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Nanoscale Positioning of Single‐Photon Emitters in Atomically Thin WSe₂

Reversible uniaxial strain tuning in atomically thin WSe ₂