Highly Stable and Spectrally Tunable Gamma Phase RbxCs1–xPbI3 Gradient‐Alloyed Quantum Dots in PMMA Matrix through A Sites Engineering

Perovskite quantum dots are emerging as new generation functional materials for display applications. The issue of perovskite “red wall” has been an obstacle for their use in display technology. In this study, the fabrication of γ‐RbxCs1–xPbI3 gradient‐alloyed quantum dots in polymeric matrix through a rational designed in situ fabrication process is reported. The formation of γ‐RbxCs1–xPbI3 gradient‐alloyed structure can be explained by considering the lattice mismatch and solubility difference between γ‐CsPbI3 and RbPbI3. The photoluminescence emission of γ‐RbxCs1–xPbI3 gradient‐alloyed quantum dots can be tuned from 675 to 620 nm with full width at half maximum of 31 nm and maximum quantum yields up to 91%. Importantly, the packaged films retained about 95% of its original photoluminescence intensity after 1000 h aging at the test conditions of 60 °C, 90% RH and 40 °C, 90% RH with 3 mW cm−2, 455 nm blue light irradiation, respectively. By integrating a red and green dual emissive film with blue Mini LEDs, a LCD backlight of a color space of ≈130% of NTSC 1931 standard is achieved with matching rate of 100%. The controlled in situ fabrication of γ‐RbxCs1–xPbI3 gradient‐alloyed quantum dots in polymeric films with tunable photoluminescence emission from 675 to 620 nm, full width at half maximum of 31 nm and quantum yields up to 91% for display backlight applications is reported here.