Scalable Dip-Coated Bragg Mirrors for Strong Light-Matter Coupling with 2D Perovskites

Abstract

We report a scalable and cost-effective method for fabricating high-performance Bragg mirrors using a bottom-up approach that combines evaporation-induced self-assembly (EISA) and dip-coating. The photonic crystals are composed of alternating mesoporous SiO2 and dense TiO2 layers, providing a high refractive index contrast (0.8). This enables strong reflectance (up to 96%) with as few as five bilayers and precise control of the photonic stop band across the visible spectrum by simply adjusting the deposition parameters. Integration of a thin film of the two-dimensional perovskite (PEA)2PbI4 leads to strong light--matter coupling at room temperature. Angle-resolved reflectance and photoluminescence measurements reveal the formation of upper and lower polariton branches, with a Rabi splitting of 90 meV. The observed polaritonic dispersion is well described by a two-level system and Green's function formalism. This work demonstrates an efficient strategy for constructing tunable optical cavities using simple solution-based methods. The combination of high optical quality, spectral tunability, and strong coupling performance positions this platform as a promising candidate for low-threshold polariton lasers, nonlinear optics, and integrated optoelectronic devices.