Self-Consistent Quantum Mechanics/Embedded Charge Study on Aggregation-Enhanced Delayed Fluorescence of Cu(I) Complexes: Luminescence Mechanism and Molecular Design Strategy
Yunli Zhang, Tengfei He, Zi-Kang Zhao, Ao Shen, Qiang Gao, Ai‐Min Ren, Zhong‐Min Su, Hui Li, Huiying Chu, Lu-Yi Zou
Abstract
To elucidate the luminescence mechanism of highly efficient blue Cu(N^N)(POP) + -type thermally activated delayed fluorescence (TADF) materials, we have selected Cu(pytfmpz)(POP) + ( 1 ) and Cu(pympz)(POP) + ( 2 ) as targets to investigate the photophysical properties in both solution and solid phases. The self-consistent electrostatic potential (ESP) embedded charge within the quantum mechanics/molecular mechanics (QM/MM) method demonstrates a greater advantage over the charge equilibrium (QEQ) in accurately calculating atomic charges and reasonably describing the polarization effect, ultimately resulting in a favorable consistency between simulation and experimental measurements. After systematic and quantitative simulation, it has been found that complex 2, with an electron-donating group of −CH 3, exhibits a much more blue-shifted spectrum and a significantly enhanced efficiency in comparison to complex 1 with −CF 3 . This is due to the widened HOMO–LUMO gap as well as the narrowed energy gap between the lowest singlet and triplet excited states (Δ E ST ), respectively. Then, the designed complex 3 is introduced with a stronger electron donor and larger tert -butyl group, which plays a key role in simultaneously suppressing the structural distortion and reducing the Δ E ST . This leads to a faster reverse intersystem crossing process than that of the two experimental complexes in solution, turning out to be a new deep-blue-emitting material with excellent TADF performance.