Exciton Diffusion and Annihilation in Nanophotonic Purcell Landscapes

Exciton Diffusion and Annihilation in Nanophotonic Purcell Landscapes

Excitons spread through diffusion and interact through exciton–exciton annihilation. Nanophotonics can counteract the resulting decrease in light emission. However, conventional enhancement treats emitters as immobile and non‐interacting. It neglects exciton redistribution between regions with diffe...

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Bibliographic Details
Published in:Advanced optical materials Vol. 10; no. 17
Main Authors: Raziman, T. V., Visser, C. Peter, Wang, Shaojun, Gómez Rivas, Jaime, Curto, Alberto G.
Format: Journal Article
Language:English
Published: Weinheim Wiley Subscription Services, Inc 01-09-2022
Subjects:
Diffusion
Emitters
exciton transport
Excitons
exciton–exciton annihilation
Light emission
Light emitting diodes
Materials science
Mie resonances
nanoparticle arrays
Optical properties
Optics
Organic crystals
Organic semiconductors
Perovskites
Photoluminescence
plasmonic resonances
Purcell effect
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Summary:Excitons spread through diffusion and interact through exciton–exciton annihilation. Nanophotonics can counteract the resulting decrease in light emission. However, conventional enhancement treats emitters as immobile and non‐interacting. It neglects exciton redistribution between regions with different enhancements and the increase in non‐radiative decay at high exciton densities. Here, the authors went beyond the localized Purcell effect to exploit exciton dynamics and turn their typically detrimental impact into additional emission. As interacting excitons diffuse through optical hotspots, the balance of excitonic and nanophotonic properties leads to either enhanced or suppressed photoluminescence. The dominant enhancement mechanisms are identified in the limits of high and low diffusion and annihilation. Diffusion lifts the requirement of spatial overlap between excitation and emission enhancements, which are harnessed to maximize emission from highly diffusive excitons. In the presence of annihilation, improved enhancement is predicted at increasing powers in nanophotonic systems dominated by emission enhancement. The guidelines are relevant for efficient and high‐power light‐emitting diodes and lasers tailored to the rich dynamics of excitonic materials such as monolayer semiconductors, perovskites, or organic crystals. Light emission in 2D semiconductors, perovskites, and molecular crystals is due to excitons. It is possible to tailor nanophotonic structures to maximize emission. Conventional nanophotonic design treats nanoscale light sources as fixed in space and non‐interacting. However, excitons spread and annihilate. This work explores the interplay of excitonic and nanophotonic properties beyond the classical Purcell effect for efficient light‐emitting devices.
ISSN:2195-1071
2195-1071
DOI:10.1002/adom.202200103