The role of momentum-dark excitons in the elementary optical response of bilayer WSe$_{2}$

TL;DR

This paper investigates how momentum-dark excitons influence the optical responses of bilayer WSe₂, combining theory and experiments to clarify their role in absorption, emission, and quantum dot formation in layered TMD semiconductors.

Contribution

It provides a comprehensive interpretation of the optical responses of bilayer WSe₂, highlighting the importance of momentum-indirect excitons through combined theoretical and experimental analysis.

Findings

Momentum-indirect excitons are crucial for understanding bilayer WSe₂ optical spectra.

The study clarifies the origin of quantum dot formation in bilayer and monolayer TMDs.

Results facilitate future opto-electronic applications of layered TMD semiconductors.

Abstract

Monolayer (ML) transition metal dichalcogenides (TMDs) undergo substantial changes in the single-particle band structure and excitonic optical response upon the addition of just one layer. As opposed to the single-layer limit, the bandgap of bilayer (BL) TMD semiconductors is indirect which results in reduced photoluminescence with richly structured spectra that have eluded a detailed understanding to date. Here, we provide a closed interpretation of the elementary optical responses of BL WSe$_2$ as a representative material for the wider class of TMD semiconductors. By combining theoretical calculations with comprehensive spectroscopy experiments, we identify the crucial role of momentum-indirect excitons for the understanding of basic absorption and emission spectra ubiquitously exhibited by various TMD BLs. Our results shed light on the origin of quantum dot (QD) formation in monolayer and bilayer crystals and will facilitate further advances directed at opto-electronic applications of layered TMD semiconductors in van der Waals heterostructures and devices.