Real-space detection and manipulation of two-dimensional quantum well states in few-layer MoS2

Quantum confinement has remarkable effects on the band structures and optoelectronic performance of semiconducting materials. The confinement of electronic states developed along van der Waals (vdW) gaps in transition metal dichalcogenides (TMDs) has unique advantages compared with those of artificial quantum wells. Here, we detected the quantized electronic states of few-layered MoS2 in real space using scanning tunneling microscope/spectroscopy. Combined with density-functional theory calculations, the quantized states were attributed to quantum-well states (QWSs), and the number of the states was strictly determined by the MoS2 layer thickness. We further regulated the QWSs of few-layered MoS2 by tuning the strength of interlayer hybridization through directly adjusting the interlayer distance. More importantly, substitutional defects in few-layered MoS2 were introduced to control the energy eigenvalues of the QWSs. Our work proves the existence of the interlayer electronic hybridization in conventional weakly coupled vdW interfaces, and provides a way to manipulate the electronic states of few-layered TMD through controlling interlayer hybridization. It also suggests potential applications of quantum-well materials in subband transitions, spin splitting, photoexcitation, and electronic devices.

Automated summary

Quantum confinement has significant effects on the band structure and optoelectronic performance of semiconducting materials. This study detected the quantized electronic states of few-layered MoS2 and investigated the influence of interlayer hybridization and substitutional defects on these states. The results provide insights into the manipulation of electronic states in few-layered TMDs and suggest potential applications in subband transitions, spin splitting, photoexcitation, and electronic devices.