发色团
化学
量子产额
激发态
光化学
三重态
杂原子
磷光
量子
联轴节(管道)
产量(工程)
系统间交叉
化学物理
有机发光二极管
单重态裂变
工作(物理)
荧光
计算化学
抗芳香性
机械有机光化学
量子效率
振动耦合
富勒烯
分子物理学
作者
Matthew C. Drummer,Rui Sun,Ana Florescu-Ciobotaru,Daniel G. Nocera
摘要
The quantum yield of a photoreagent's excited state imposes a ceiling on the overall efficiency of a photoprocess. Organic sensitizers with large or near-unity triplet excited-state quantum yields (ΦT) are often designed by implementing spin-orbit coupling (SOC) through the incorporation of heavy-atom substituents or heteroatoms with nonbonding electrons, which typically come at the cost of shortened triplet excited-state lifetimes, lowered triplet energies, and/or poor photostability. We show here that the disposition of organic chromophores in an H-dimer offers a path to near-unity ΦT while maintaining a long excited-state lifetime and preserving the excited-state energy. Cofacially poising pyrenes on a xanthene scaffold (Py2Xanth) furnishes H-dimer photophysics with a near-unity ΦT of 97% while preserving a 2.1 eV triplet energy and a long-lived, 180 μs, triplet lifetime. Given these properties, we show Py2Xanth to be a highly efficient triplet photosensitizer. This work reveals that H-dimer coupling of chromophores is a promising design principle for the development of highly efficient, photostable, organic photosensitizers that avoid the penalties associated with SOC modifications.
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