Electrically tunable dipolar interactions between layer-hybridized excitons

TL;DR

This paper investigates how electric fields can tune interactions between hybrid excitons in bilayer WSe2, revealing regimes with weak and strong dipolar interactions, and providing insights for future experimental exploration.

Contribution

It introduces a microscopic, material-specific theory demonstrating electrical control over hybrid exciton interactions in layered semiconductors.

Findings

Weak inter-excitonic interactions at low electric fields

Strong dipole-dipole repulsion at high electric fields

Spectral blue-shifts and anomalous diffusion observed

Abstract

Transition-metal dichalcogenide bilayers exhibit a rich exciton landscape including layer-hybridized excitons, i.e. excitons which are of partly intra- and interlayer nature. In this work, we study hybrid exciton-exciton interactions in naturally stacked WSe$_2$ homobilayers. In these materials, the exciton landscape is electrically tunable such that the low-energy states can be rendered more or less interlayer-like depending on the strength of the external electric field. Based on a microscopic and material-specific many-particle theory, we reveal two intriguing interaction regimes: a low-dipole regime at small electric fields and a high-dipole regime at larger fields, involving interactions between hybrid excitons with a substantially different intra- and interlayer composition in the two regimes. While the low-dipole regime is characterized by weak inter-excitonic interactions between intralayer-like excitons, the high-dipole regime involves mostly interlayer-like excitons which display a strong dipole-dipole repulsion and give rise to large spectral blue-shifts and a highly anomalous diffusion. Overall, our microscopic study sheds light on the remarkable electrical tunability of hybrid exciton-exciton interactions in atomically thin semiconductors and can guide future experimental studies in this growing field of research.