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Interlayer Coupling and Pressure Engineering in Bilayer MoS2

Wei Qiao, Hao Sun, Xiaoyue Fan, Meiling Jin, Haiyang Liu, Tianhong Tang, Lei Xiong, Binghui Niu, Xiang Li, Gang Wang

2022Crystals11 citationsDOIOpen Access PDF

Abstract

Controlling the interlayer coupling by tuning lattice parameters through pressure engineering is an important route for tailoring the optoelectronic properties of two-dimensional materials. In this work, we report a pressure-dependent study on the exciton transitions of bilayer MoS2 exfoliated on a diamond anvil surface. The applied hydrostatic pressure changes from ambient pressure up to 11.05 GPa using a diamond anvil cell device. Raman, photoluminescence, and reflectivity spectra at room temperature are analyzed to characterize the interlayer coupling of this bilayer system. With the increase of pressure, the indirect exciton emission disappears completely at about 5 GPa. Importantly, we clearly observed the interlayer exciton from the reflectivity spectra, which becomes invisible at a low pressure around 1.26 GPa. This indicates that the interlayer exciton is very sensitive to the hydrostatic pressure due to the oscillator strength transfer from the direct transition to the indirect one.

Topics & Concepts

ExcitonRaman spectroscopyBilayerHydrostatic pressurePhotoluminescenceMaterials scienceCoupling (piping)Spectral lineReflectivityAmbient pressureHydrostatic equilibriumCondensed matter physicsOptoelectronicsChemistryOpticsComposite materialMembraneThermodynamicsAstronomyPhysicsQuantum mechanicsBiochemistry2D Materials and ApplicationsPerovskite Materials and ApplicationsMXene and MAX Phase Materials