Machine-learning-assisted performance improvements for multi-resonance thermally activated delayed fluorescence molecules

With favorable colour purity, multi-resonance thermally activated delayed fluorescence (MR-TADF) molecules exhibit enormous potential in high-definition displays. Due to the relatively small chemical space of MR-TADF molecules, it is challenging to improve molecular performance through domain-specif...

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Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2023-12, Vol.26 (1), p.144-152
Main Authors: Cai, Wanlin, Zhong, Cheng, Ma, Zi-Wei, Cai, Zhuan-Yun, Qiu, Yue, Sajid, Zubia, Wu, De-Yin
Format: Article
Language:English
Subjects:
Color
Energy gap
Fluorescence
High definition
Machine learning
Molecular orbitals
Morphing
Optoelectronics
Purity
Resonance
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Summary:With favorable colour purity, multi-resonance thermally activated delayed fluorescence (MR-TADF) molecules exhibit enormous potential in high-definition displays. Due to the relatively small chemical space of MR-TADF molecules, it is challenging to improve molecular performance through domain-specific expertise alone. To address this problem, we focused on optimizing the classic molecule, DABNA-1 , using machine learning (ML). Molecular morphing operations were initially employed to generate the adjacent chemical space of DABNA-1 . Subsequently, a machine learning model was trained with a limited database and used to predict the properties throughout the generated chemical space. It was confirmed that the top 100 molecules suggested by machine learning present excellent electronic structures, characterized by small reorganization energy and singlet-triplet energy gaps. Our results indicate that the improvement in electronic structures can be elucidated through the view of the molecular orbital (MO). The results also reveal that the top 5 molecules present weaker vibronic peaks of the emission spectrum, demonstrating higher colour purity when compared to DABNA-1 . Notably, the M2 molecule presents a high RISC rate, indicating its promising future as a high-efficiency MR-TADF molecule. Our machine-learning-assisted approach facilitates the rapid optimization of classical molecules, addressing a crucial requirement within the organic optoelectronic materials community. Machine learning is used to advance the performance of multi-resonance thermally activated delayed fluorescence molecules, with a specific focus on improving colour purity and RISC rate simultaneously.
ISSN:1463-9076
1463-9084
DOI:10.1039/d3cp04441f