Fast, Efficient, Narrowband Room-Temperature Phosphorescence from Metal-Free 1,2-Diketones: Rational Design and Mechanism

Abstract

We report metal-free organic 1,2-diketones that exhibit fast and highly efficient room-temperature phosphorescence (RTP) with high colour 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. Detailed mechanistic studies using ultrafast spectroscopy, single-crystal X-ray structure analysis, and theoretical calculations revealed picoseconds intersystem crossing (ISC) followed by RTP from a planar conformation. Notably, the phosphorescence rate constant kp was unambiguously established as ~5000 s–1, which is comparable to that of platinum porphyrins (representative heavy-metal phosphor). This inherently large kp enabled the high-efficiency RTP across diverse molecular environments, thus complementing the streamlined persistent RTP approach. The mechanism behind the photofunction has been elucidated as follows: (1) the large kp is due to efficient intensity borrowing of the T1 state from bright S3 state, (2) the rapid ISC occurs from S1 to T3 state because those states are nearly isoenergetic and have a considerable spin–orbit coupling, and (3) the narrowband emission results from the minimal geometry changes between the T1 and S0 state. Such mechanistic understanding based on molecular orbitals, as well as the structure–RTP property relationship study, highlighted design principles embodied by the diketone planar conformer. The fast RTP strategy enables developing organic phosphors with emissions independent of environmental conditions, thereby offering alternatives to precious-metal based phosphors.