1. Reduced Intrinsic Non‐Radiative Losses Allow Room‐Temperature Triplet Emission from Purely Organic Emitters
- Author
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Lihui Jiang, Sebastian Reineke, Felix Fries, Karl Leo, Olaf Zeika, Yingping Zou, Shun-Qi Xu, Wenlan Liu, Tian-Yi Li, Denis Andrienko, Yungui Li, Reinhard Scholz, Xinliang Feng, Charusheela Ramanan, and Simone Lenk
- Subjects
Materials science ,Mechanical Engineering ,Exciton ,Quantum yield ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Molecular physics ,0104 chemical sciences ,Afterglow ,Persistent luminescence ,Mechanics of Materials ,Molecular vibration ,Excited state ,Radiative transfer ,General Materials Science ,0210 nano-technology ,Phosphorescence - Abstract
Persistent luminescence from triplet excitons in organic molecules is rare, as fast non-radiative deactivation typically dominates over radiative transitions. This work demonstrates that the substitution of a hydrogen atom in a derivative of phenanthroimidazole with an N-phenyl ring can substantially stabilize the excited state. This stabilization converts an organic material without phosphorescence emission into a molecular system exhibiting efficient and ultralong afterglow phosphorescence at room temperature. Results from systematic photophysical investigations, kinetic modeling, excited-state dynamic modeling, and single-crystal structure analysis identify that the long-lived triplets originate from a reduction of intrinsic non-radiative molecular relaxations. Further modification of the N-phenyl ring with halogen atoms affects the afterglow lifetime and quantum yield. As a proof-of-concept, an anticounterfeiting device is demonstrated with a time-dependent Morse code feature for data encryption based on these emitters. A fundamental design principle is outlined to achieve long-lived and emissive triplet states by suppressing intrinsic non-radiative relaxations in the form of molecular vibrations or rotations.
- Published
- 2021
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