Non-Generic Dispersion of Excitons in the Bulk of WSe$_2$

TL;DR

This study combines experimental and theoretical methods to investigate exciton dispersion in bulk WSe$_2$, revealing non-generic behavior and suggesting a momentum-dependent particle-hole interaction influences exciton properties.

Contribution

It provides new insights into exciton dispersion in WSe$_2$ by combining EELS measurements with DFT calculations, highlighting the role of momentum-dependent interactions.

Findings

Deviations from quadratic dispersion along $ ext{ΓK}$-direction.

Evidence for momentum-dependent particle-hole interactions.

Analysis suggests single-particle band structure influences exciton behavior.

Abstract

We combine electron energy-loss spectroscopy (EELS) and density functional theory (DFT) calculations to study the dispersion and effective mass of excitons in the bulk of WSe$_2$. Our EELS data suggest substantial deviations from the generic quadratic momentum dependence along the $\Gamma K$-direction. From the DFT-derived Kohn-Sham states we deduce the EELS response without the inclusion of particle-hole attraction to study the possible role of the single-particle band structure on the exciton behavior. Based on this analysis we argue in favor of a strongly momentum dependent particle-hole interaction in WSe$_2$ and other group VI-transition-metal dichalcogenides.