Litcius/Paper detail

Impact of Δ<i>E</i><sub>ST</sub> on Delayed Fluorescence Rate, Lifetime, and Intensity Ratio of Tetrahedral Cu(I) Complexes: Theoretical Simulation in Solution and Solid Phases

Tengfei He, Ai‐Min Ren, Guohui Li, Zexing Qu, Jing-Fu Guo, Xue-Li Hao, Yuan-Nan Chen, Lu Shen, Yunli Zhang, Lu-Yi Zou

2021The Journal of Physical Chemistry Letters20 citationsDOI

Abstract

Profound understanding of the luminescence mechanism and structure–property relationship is vital for Cu(I) thermally activated delayed fluorescence (TADF) emitters. Herein, we theoretically simulated luminescent behavior in both solution and solid phases for two Cu(I) complexes and found the following: (i) The strengthened spin–orbit coupling (SOC) effect by more dx2–y2 orbital contributions and well-restricted structural distortion via remarkable intramolecular interaction in [Cu(dmp)(POP)]+ enable the emission at room temperature to be a mixture of direct phosphorescence (10%) and TADF (90%). (ii) Benefiting from enhanced steric hindrance and the electron-donating ability of the paracyclophane group, the narrowed S1–T1 energy separation (ΔEST) in [Cu(dmp)(phanephos)]+ accelerates the reverse intersystem crossing, promoting the TADF rate (1.88 × 105 s–1) and intensity ratio (98.3%). These results indicate that the small ΔEST is superior for reducing the lifetime and that the strong SOC stimulates the phosphorescence to compete with TADF, which are both conducive to avoiding collision-induced exciton quenching and reducing the roll-off in devices.

Topics & Concepts

Intersystem crossingPhosphorescenceLuminescenceIntramolecular forceFluorescenceQuenching (fluorescence)Materials scienceSteric effectsPhotochemistryExcitonChemistrySinglet stateOptoelectronicsAtomic physicsStereochemistryOpticsCondensed matter physicsPhysicsExcited stateOrganic Light-Emitting Diodes ResearchLuminescence and Fluorescent MaterialsLanthanide and Transition Metal Complexes