Reducing the detachment of ligands on all-inorganic cesium lead bromide perovskite quantum dots (CsPbBr PQDs) presents a significant challenge to their practical applications, despite their remarkable optoelectronic properties. Herein, a novel strategy was introduced to passivate the surface defects of CsPbBr PQDs by employing short-chain surface ligands and functional groups within a polymer matrix to enhance their processability. Guanidinopropanoic acid (GPA) was employed as a coligand alongside oleic acid and oleylamine to synthesize CsPbBr-GPA PQDs via the hot injection method. A nitrogen-containing, superhydrophobic mesoporous polymer, poly(divinylbenzene)-vinylimidazole (PDVB-Vim), was utilized as an innovative encapsulation material for CsPbBr PQDs, resulting in the formation of the CsPbBr-GPA@PDVB-Vim composite. CsPbBr-GPA PQDs were successfully protected from unfavorable external stimulation, such as water and UV light, by the protective PDVB-Vim. CsPbBr-GPA@PDVB-Vim retains over 76% of its initial photoluminescence intensity after 31 days in water and 68% after 96 h of continuous exposure to 365 nm UV irradiation at an intensity of 15 mW·cm. The screen printing of CsPbBr-GPA@PDVB-Vim with methyl methacrylate, butyl methacrylate, and styrene demonstrates its potential as a stable light conversion material for wearable devices. This breakthrough may pave the way for further advancements in using CsPbBr-GPA@PDVB-Vim as a highly stable photoluminescent material for wearable luminescent textiles and light conversion applications.
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