Measurements of absolute bandgap deformation-potentials of optically-bright bilayer WSe2

Abstract

Bilayers of transition-metal dichalcogenides show many exciting features, including long-lived interlayer excitons and wide bandgap tunability using strain. Not many investigations on experimental determinations of deformation potentials relating changes in optoelectronic properties of bilayer WSe2 with the strain are present in the literature. Our experimental study focuses on three widely investigated high-symmetry points, Kc, Kv, and Qc, where subscript c (v) refers to the conduction (valence) band, in the Brillouin zone of bilayer WSe2. Using local biaxial strains produced by nanoparticle stressors, a theoretical model, and by performing the spatially- and spectrally-resolved photoluminescence measurements, we determine absolute deformation potential of -5.10 0.24 eV for Qc-Kv indirect bandgap and -8.50 0.92 eV for Kc-Kv direct bandgap of bilayer WSe2. We also show that ≈0.9% biaxial tensile strain is required to convert an indirect bandgap bilayer WSe2 into a direct bandgap semiconductor. Moreover, we also show that a relatively small amount of localized strain ≈0.4% is required to make a bilayer WSe2 as optically bright as an unstrained monolayer WSe2. The bandgap deformation potentials measured here will drive advances in flexible electronics, sensors, and optoelectronic- and quantum photonic- devices through precise strain engineering.

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