余辉
发光
材料科学
纳米技术
光电子学
分子内力
电子
量子点
光化学
光致发光
化学物理
持续发光
共价键
桥接(联网)
热的
工作(物理)
碳纤维
氢
作者
Kang Shao,Qibin Dong,Ying Meng,Jiahong Chen,Haoru Wen,Xueting Wang,Zaifa Pan,Shiyi Ye,Yi-Xiang Wang
摘要
ABSTRACT Carbon dots (CDs) have emerged as promising luminescent materials, yet their practical applications are hindered by short afterglow durations (typically seconds) and limited environmental stability. Here, we report a universal matrix‐engineering strategy that enables minute‐scale, multicolor afterglow in CDs by constructing an intramolecular charge‐transfer (ICT)‐driven electron donor–acceptor (D–A) system. Using tailored matrices of boric acid, silica, and cyanuric acid, we achieve robust host–guest interactions (e.g., hydrogen bonding, covalent linkage, and charge‐transfer states) that synergistically enhance confinement, stabilize triplet excitons, and promote long‐lived exciplex formation. The resulting composites exhibit ultralong afterglow with naked‐eye‐visible durations exceeding 240 s and a record lifetime of up to 300 s, alongside exceptional aqueous and thermal stability. Mechanistic studies reveal that pre‐existing ICT states in CDs facilitate electron‐cascade transfer, generating spatially separated charge‐separated states. Their delayed recombination bypasses spin‐forbidden decay pathways. We further demonstrate the versatility of these materials in dynamic information encryption, flexible films, and hydrogel‐based systems, highlighting their potential for advanced anti‐counterfeiting and smart displays. This work establishes a foundational framework for designing long‐persistent luminescent materials via molecular‐level D–A alignment, bridging the gap between organic and inorganic phosphors.
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