Giant Rabi splitting and polariton photoluminescence in an all solution-deposited dielectric microcavity

TL;DR

This paper demonstrates a fully solution-processed dielectric microcavity with strong light-matter coupling, achieving giant Rabi splitting and enhanced photoluminescence, offering a low-cost, flexible alternative to traditional microcavities.

Contribution

It introduces a novel all-solution-processed polariton microcavity with record Rabi splitting and improved exciton dynamics, expanding applications in flexible optoelectronics.

Findings

Achieved over 400 meV Rabi-splitting in the microcavity.

Observed a tenfold increase in critical excitation density for bimolecular annihilation.

Demonstrated uniform dispersion along the lower polariton mode.

Abstract

Planar microcavity polaritons have recently emerged as a promising technology for improving several performance characteristics of organic light-emitting diodes, photodiodes and photovoltaics. To form polaritons and achieve enhanced performance, traditional microcavities with high reflectivity mirrors are fabricated by energy-intensive physical vapor deposition methods, which restrict their use in applications requiring flexibility and low cost. Here, for the first time, we demonstrate a dielectric all-solution-processed polariton microcavity consisting of Rhodamine 6G films in a poly(vinyl alcohol) matrix, exhibiting more than 400 meV Rabi-splitting and photoluminescence with uniform dispersion along the lower polariton mode. Our fully automated deposition and annealing fabrication protocol played a key role in preventing interlayer mixing and producing high optical-quality polariton microcavities, enabling us to observe enhanced scattering of reservoir excitons to the lower polariton and to explore the effects of strong coupling on bimolecular interactions. Notably, we found that polariton microcavities exhibit a more than 10-fold increase in the critical excitation density for bimolecular annihilation compared to bare Rhodamine 6G films. This enhancement can only be partially attributed to the sub-3-fold measured enhancement in radiative lifetime, highlighting the critical role of strong coupling in the influence of molecular dynamics.