材料科学
发光
钙钛矿(结构)
纳米技术
光电子学
热的
灵活性(工程)
发光二极管
卤化物
纳米颗粒
制作
量子点
纳米材料
有色的
可靠性(半导体)
堇青石
陶瓷
纳米-
光致发光
作者
Yu Jia,Hongxing Wang,Xuan Zhang,Jianyong Yu,Yang Si
标识
DOI:10.1002/adma.202523117
摘要
High-temperature flexible luminescent materials-enabling information transmission, safety monitoring, and operational reliability at extreme temperatures-have great potential for demanding applications such as metallurgy, petrochemical engineering, and fire protection. However, developing luminescent materials that integrate multicolor emission, high color purity, and mechanical flexibility at high temperatures remains an appealing yet formidable challenge. Herein, inspired by the multilevel architecture protecting pigments in the vividly colored butterfly's wing, we present a multiscale self-confinement strategy to fabricate flexible perovskite luminescent nanofibrous meta-aerogels with bioinspired thermal armor. Benefiting from multidimensional encapsulation to shield perovskite from extrinsic environmental perturbations and directional confinement to suppress ion migration and particle agglomeration, the biomimetic flexible meta-aerogels achieve stable luminescence up to 600 K. The resulting meta-aerogels exhibit tunable emission from blue to red and narrow-band emission (full width at half maximum < 45 nm). Furthermore, the meta-aerogels demonstrate excellent recovery after 500 compression cycles and temperature-invariant superelasticity. These advancements highlight the significant potential of these materials for next-generation flexible lighting and display applications under extreme conditions.
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