Tunable Fluorescein-Encapsulated Zeolitic Imidazolate Framework-8 Nanoparticles for Solid-State Lighting

A series of fluorescein-encapsulated zeolitic imidazolate framework8 (fluorescein@ZIF-8) luminescent nanoparticles with a scalable guest loading has been fabricated and characterized. The successful encapsulation of the organic dye (fluorescein) is supported by both experimental evidence and theoretical simulations. The measured optical band gap is found to be comparable with the computed values of a hypothetical guest-host system. Isolated monomers and aggregate species of fluorescein confined in ZIF-8 nanocrystals have been systematically investigated through fluorescence lifetime spectroscopy. The quantum yield (QY) of the obtained solid-state materials is particularly high (QY similar to 98%), especially when the concentration of the fluorescein guest is low. Combining a blue LED chip and a thin photoactive film of fluorescein@ZIF-8, we demonstrate a device with good optical tunability for multicolor and white light emissions. Additionally, we show that the fluorescein@ZIF-8 nanoparticles exhibit an improved photostability due to the shielding effect conferred by the nanoconfinement of the host framework, making them promising candidates for practical applications such as solid-state lighting, photonics, and optical communications.

Automated summary

A series of luminescent nanoparticles, fluorescein@ZIF-8, with scalable guest loading, have been successfully fabricated and characterized, supported by experimental evidence and theoretical simulations. The materials exhibit high quantum yield, especially at low concentrations of fluorescein. Furthermore, the nanoparticles show improved photostability due to nanoconfinement within the host framework, making them promising candidates for practical applications such as solid-state lighting and optical communications.