Abstract
Using mesoporous SiO(2) to encapsulate CsPbBr(3) nanocrystals is one of the best strategies to exploit such materials in devices. However, the CsPbBr(3)/SiO(2) composites produced so far do not exhibit strong photoluminescence emission and, simultaneously, high stability against heat and water. We demonstrate a molten-salts-based approach delivering CsPbBr(3)/mesoporous-SiO(2) composites with high PLQY (89 ± 10%) and high stability against heat, water, and aqua regia. The molten salts enable the formation of perovskite nanocrystals and other inorganic salts (KNO(3)-NaNO(3)-KBr) inside silica and the sealing of SiO(2) pores at temperatures as low as 350 °C, representing an important technological advancement (analogous sealing was observed only above 700 °C in previous reports). Our CsPbBr(3)/mesoporous-SiO(2) composites are attractive for different applications: as a proof-of-concept, we prepared a white-light emitting diode exhibiting a correlated color temperature of 7692K. Our composites are also stable after immersion in saline water at high temperatures (a typical underground environment of oil wells), therefore holding promise as oil tracers.