ABSTRACT Ionic thermally activated delayed fluorescence (iTADF) materials are promising for organic optoelectronics due to their solution processability and structural tunability, yet the synergistic regulation of reverse intersystem crossing (RISC) by heteroatom anchoring, heavy‐atom effects, and vibronic coupling remains underexplored. Four molecules (AC‐TPPO + , AC‐TPPS + , AC‐TPPOBr, and AC‐TPPSBr) are systematically investigated via density functional theory (DFT), TD‐DFT, and excited‐state dynamics. All molecules feature twisted donor‐acceptor conformations, enabling spatial separation of frontier molecular orbitals and a small singlet–triplet energy gap (Δ E ST ) for RISC. The bromide counterion (Br − ) induces a heavy‐atom effect, enhancing spin‐orbit coupling strength and accelerating RISC rates by two orders of magnitude. Low‐to‐medium‐frequency vibrations further facilitate RISC by driving S 1 and T 1 potential energy surfaces to near‐degeneracy. The optimal AC‐TPPOBr achieves a high delayed fluorescence quantum yield ( Φ DF = 74.88%) with nearly 100% room‐temperature TADF contribution. This work provides a synergistic design paradigm and theoretical guidance for high‐performance OLED emitters.
Meng et al. (Thu,) studied this question.