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Abstract
We report metal-free organic 1,2-diketones that exhibit fast and highly efficient room-temperature phosphorescence (RTP) with high color purity under various conditions, including solutions. RTP quantum yields reached 38.2% in solution under Ar, 54% in a polymer matrix in air, and 50% in a crystalline solids in air. Moreover, the narrowband RTP consistently dominated the steady-state emission, regardless of the molecular environment. A detailed investigation of the emission mechanism using ultrafast spectroscopy, single-crystal X-ray structure analysis, and theoretical calculations revealed picoseconds intersystem crossing followed by RTP from a planar conformation. Thus, we attribute the high efficiency RTP across diverse molecular environments to an inherent ~5000-s–1 phosphorescence rate constant comparable to that of platinum porphyrin complexes. The planar conformation reflected a design principle for fast and narrowband RTP. This strategy complements the streamlined persistent RTP approach and enables the development of organic phosphors with emissions independent of environmental conditions, thereby offering alternatives to precious-metal based phosphors.
Supplementary materials
Title
Supporting Information
Description
Synthesis, characterization, and single-crystal X-ray structure analysis of 1c; detailed procedures of evaluating quantum yields and lifetimes; additional photophysical properties; (TD)DFT calculations.
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