AI Article Synopsis
- - The study focuses on improving TMD-based polariton devices, like polariton lasers and optical switches, by exploring the dynamics of their excited states using ultrafast pump-probe optical spectroscopy.
- - The research reveals that the polariton system's transient response shows rapid initial decay (0.15-0.25 ps) versus its calculated intrinsic lifetime (0.11-0.20 ps), followed by a longer decay (over 100 ps) attributed to the exciton reservoir's dynamics.
- - Overall, these findings enhance the understanding of TMD-based polariton systems and their potential for efficient optical processes in various device applications.
Article Abstract
The dynamics of strongly coupled polariton systems integrated with 2D transition metal dichalcogenides (TMDs) is key to enabling efficient coherent processes and achieving high-performance TMD-based polaritonic devices, such as ultralow-threshold polariton lasers and ultrafast optical switches. However, there has been a lack of a comprehensive understanding of the excited state dynamics in TMD-based polariton systems. In this work, ultrafast pump-probe optical spectroscopy is used to investigate the room temperature dynamics of the polariton systems consisting of TMD monolayer excitons strongly coupled with Bloch surface waves (BSWs) supported by all-dielectric photonic structures. The transient response is found for both above-exciton energy pumping and polariton-resonant pumping. The excited state population and ultrafast coherent coupling of the exciton reservoir and lower polariton (LP) branch are observed for resonant pumping. Moreover, it is found that the transient response of the LP first decays on a short-time scale of 0.15-0.25 ps compared to the calculated intrinsic lifetime of 0.11-0.20 ps, and is followed by a longer decay (>100 ps) due to the dynamical evolution of the exciton reservoir. The results provide a fundamental understanding of the dynamics of TMD-based polariton systems while showing the potential for achieving efficient coherent optical processes for device applications.
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| http://dx.doi.org/10.1002/adma.202404286 | DOI Listing |
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