Boosting quantum yields in 2D semiconductors via proximal metal plates

TL;DR

This study demonstrates that placing monolayer TMDs near a metallic substrate with dielectric layers can significantly enhance quantum yield by screening exciton interactions, leading to more efficient 2D light emitters.

Contribution

It introduces a method to suppress exciton-exciton interactions in 2D semiconductors using proximal metal plates, improving emission efficiency.

Findings

Quantum yield increased by an order of magnitude.

Exciton-exciton annihilation rate reduced.

Screening effect explained by a semiclassical model.

Abstract

Monolayer transition metal dichalcogenides (1L-TMDs) have tremendous potential as atomically thin, direct bandgap semiconductors that can be used as convenient building blocks for quantum photonic devices. However, the short exciton lifetime due to the defect traps and the strong exciton-exciton interaction in TMDs has significantly limited the efficiency of exciton emission from this class of materials. Here, we show that exciton-exciton dipolar field interaction in 1L-WS2 can be effectively screened using an ultra-flat Au film substrate separated by multilayers of hexagonal boron nitride. Under this geometry, dipolar exciton-exciton interaction becomes quadrupole-quadrupole interaction because of effective image dipoles formed inside the metal. The suppressed exciton-exciton interaction leads to a significantly improved quantum yield by an order of magnitude, which is also accompanied by a reduction in the exciton-exciton annihilation (EEA) rate, as confirmed by time-resolved optical measurements. A semiclassical model accounting for the screening of the dipole-dipole interaction qualitatively captures the dependence of EEA on exciton densities. Our results suggest that fundamental EEA processes in the TMD can be engineered through proximal metallic screening, which represents a practical approach towards high-efficiency 2D light emitters.