Large trion binding energy in monolayer WS2 via strain-enhanced electron-phonon coupling

Abstract

Transition metal dichalcogenides and related layered materials in their monolayer and a few layers thicknesses regime provide a promising optoelectronic platform for exploring the excitonic- and many-body physics. Strain engineering has emerged as a potent technique for tuning the excitonic properties favorable for exciton-based devices. We have investigated the effects of nanoparticle-induced local strain on the optical properties of exciton, X0, and trion, X-, in monolayer WS2. Biaxial tensile strain up to 2.0% was quantified and verified by monitoring the changes in three prominent Raman modes of WS2: E12g(), A1g, and 2LA(M). We obtained a remarkable increase of 34 meV in X- binding energy with an average tuning rate of 17.5 2.5 meV/% strain across all the samples irrespective of the surrounding dielectric environment of monolayer WS2 and the sample preparation conditions. At the highest tensile strain of ≈2%, we have achieved the largest binding energy ≈100 meV for X-, leading to its enhanced emission intensity and thermal stability. By investigating strain-induced linewidth broadening and deformation potentials of both X0 and X- emission, we elucidate that the increase in X- binding energy is due to strain-enhanced electron-phonon coupling. This work holds relevance for future X--based nano-opto-electro-mechanical systems and devices.

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