系统间交叉
化学
吩恶嗪
接受者
光化学
有机发光二极管
光敏剂
吩噻嗪
催化作用
组合化学
有机化学
单重态
激发态
图层(电子)
医学
物理
核物理学
药理学
凝聚态物理
作者
Manpreet Singh,M. Kumar,Vandana Bhalla
标识
DOI:10.1002/asia.202400033
摘要
Abstract The work presented in the manuscript describes a simple strategy for transforming thermally activated delayed fluorescent organic light‐emitting diodes (TADF OLEDs) compound 10‐(dibenzo[ a,c ]phenazin‐11‐yl)‐10 H ‐phenoxazine ( DPZ‐PXZ ) into type I photosensitizer 10‐(dibenzo[ a,c ]phenazin‐11‐yl)‐10 H ‐phenothiazine ( DPZ‐PHZ ) by strategically introducing sulfur atom in the photosensitizing core. The synthesized compound DPZ‐PHZ exhibits aggregation‐induced enhancement (AIE) and through‐space charge transfer (TSCT) characteristics and generates red emissive assemblies in mixed aqueous media. The original compound DPZ‐PXZ exhibits well‐separated HOMO and LUMO levels and is reported to have highly efficient reverse intersystem crossing (RISC). In comparison, the incorporation of sulfur atom in the phenothiazine donor regulates the electronic communication between donor and acceptor units and promotes the intersystem crossing (ISC) in DPZ‐PHZ molecules. Interestingly, compound DPZ‐PHZ exhibits rapid activation of aerial oxygen for instant generation of superoxide radical anion. Backed by excellent type I photosensitizing activity, DPZ‐PHZ assemblies have high catalytic potential for the synthesis of benzimidazoles, benzothiazoles and quinazolines derivatives under mild reaction conditions. The work presented in the manuscript provides an insight into the combination of heavy atom approach and TSCT for achieving adequate electronic communication between donor and acceptor units, balanced RISC/ISC, and stabilized‐charge separated state for the development of efficient type I photosensitizing assemblies.
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