The Role of Chalcogen Vacancies in Single Photon Emission from Monolayer Tungsten Dichalcogenides (2412.03686v1)

Abstract: Understanding the mechanism of single photon emission (SPE) in two-dimensional (2D) materials is an unsolved problem important for quantum optical materials and the development of quantum information applications. In 2D transition metal dichalcogenides (TMDs) such as tungsten diselenide (WSe$_2$), quantum emission has been broadly attributed to exciton localization from atomic point defects, yet the precise microscopic picture is not fully understood. This work presents a new framework, supported by both computational and experimental evidence, to explain both the origins of facile SPE in WSe2 and the relative scarcity of SPE in the related 2D TMD, tungsten disulfide (WS$_2$). A vertical divacancy configuration of selenium creates a defect-centered, direct energy gap in the band structure of WSe2, giving rise to highly localized, radiative transitions. This configuration is shown to be energetically preferred in the monolayer lattice, which is reflected in the abundant experimental observation of SPE in WSe2 both from the literature and this work. In contrast, the same vertical divacancy configuration in WS2 does not create direct localized transitions, consistent with scarce observations of SPE in that material. By revealing a single mechanism in tungsten-based TMDs that addresses the prevalence of SPE and is consistent between theory and experiment, these results provide a framework for better understanding the rules governing the atomic origins of single photon emission in TMDs.