Abstract
Three-dimensional confinement allows semiconductor quantum dots to exhibit size-tunable electronic and optical properties that enable a wide range of opto-electronic applications from displays, solar cells and bio-medical imaging to single-electron devices. Additional modalities such as spin and valley properties in monolayer transition metal dichalcogenides provide further degrees of freedom requisite for information processing and spintronics. In nanostructures, however, spatial confinement can cause hybridization that inhibits the robustness of these emergent properties. Here, we show that laterally-confined excitons in monolayer MoS2 nanodots can be created through top-down nanopatterning with controlled size tunability. Unlike chemically-exfoliated monolayer nanoparticles, the lithographically patterned monolayer semiconductor nanodots down to a radius of 15 nm exhibit the same valley polarization as in a continuous monolayer sheet. The inherited bulk spin and valley properties, the size dependence of excitonic energies, and the ability to fabricate MoS2 nanostructures using semiconductor-compatible processing suggest that monolayer semiconductor nanodots have potential to be multimodal building blocks of integrated optoelectronics and spintronics systems.
Highlights
Semiconductor quantum dots (QDs) exhibit optical properties that can be tailored for diverse opto-electronic applications ranging from light emitting devices[1], energy harvesting technologies[2], and medical therapies[3], to enabling rich fundamental advances in low-dimensional spintronics and quantum information processing[4,5,6]
Our measurements show that ML transition metal dichalcogenides (TMDs) nanodots in the weak confinement regime inherit the valley-selective band structure of the continuous ML while exhibiting controlled optical properties that depend on their lateral size
The evolution of valley polarization in TMD nanostructures with lateral confinement has not been explored in previous experiments
Summary
Semiconductor quantum dots (QDs) exhibit optical properties that can be tailored for diverse opto-electronic applications ranging from light emitting devices[1], energy harvesting technologies[2], and medical therapies[3], to enabling rich fundamental advances in low-dimensional spintronics and quantum information processing[4,5,6]. In the weak confinement regime, with radius R greater than the exciton Bohr radius aB, optical properties display size-tunable finite size effects in electronic structure, whereas the strong confinement (R aB) enables discrete energy levels and fermionic exciton behavior useful for quantum devices. 0 20 25 30 35 40 R (nm) optical properties and investigation of valley polarization in a regime of controlled lateral dimension with the possibility for integration into more complex devices for opto-electronic and valleytronics applications
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