硫族元素
量子产额
结晶学
分子间力
系统间交叉
构象异构
化学
单重态
晶体结构
激发态
分子
单线态氧
产量(工程)
单体
材料科学
Crystal(编程语言)
基态
光化学
晶体工程
星团(航天器)
自组装
圆二色性
作者
X.L. Che,Lishan Sun,Chenglong Liao,Hongwei Ji,Yanjun Gong,Yanke Che,Jincai Zhao
摘要
ABSTRACT Herein, we report a triple‐acceptor donor–acceptor (D–A) molecule designed with three consecutively linked acceptors to confer substantial conformational flexibility. This conformational flexibility translates into distinct crystalline packing modes, which yield strikingly different photosensitizing efficiencies. Notably, a unique crystal structure is formed by the self‐assembly of six distinct conformers into a circular architecture via intermolecular chalcogen bonding, an arrangement unambiguously confirmed by single‐crystal X‐ray diffraction. The cyclic assembly delivers an impressive solid‐state 1 O 2 quantum yield of 80%, a value far higher than that of the solution‐dispersed monomer (62%) and a non‐cyclically packed polymorph with both chalcogen bonds and π‐interactions between A groups (43%). This enhancement stems from the unique circular packing motif that increases the energy mismatch between the singlet excited state (S 1 ) and singlet ground state (S 0 ) to facilitate intersystem crossing (ISC), while concurrently suppressing π–π stacking–induced quenching. The generality of this strategy is further demonstrated by a heavy‐atom‐containing analogue, which achieves a similarly high 1 O 2 quantum yield of 84% in its chalcogen‐bond‐directed circular assembly (comprising three conformers), markedly outperforming a counterpart polymorph (45%) with both chalcogen bonds and π‐interactions between A groups and non‐circular packing. These findings establish a versatile and robust approach for developing high‐performance crystalline photosensitizers.
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