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Efficient, narrow-band, and stable electroluminescence from organoboron-nitrogen-carbonyl emitter
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Efficient, narrow-band, and stable electroluminescence from organoboron-nitrogen-carbonyl emitter
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Journal Article
Efficient, narrow-band, and stable electroluminescence from organoboron-nitrogen-carbonyl emitter
2024
Overview
Organic light-emitting diodes (OLEDs) exploiting simple binary emissive layers (EMLs) blending only emitters and hosts have natural advantages in low-cost commercialization. However, previously reported OLEDs based on binary EMLs hardly simultaneously achieved desired comprehensive performances, e.g., high efficiency, low efficiency roll-off, narrow emission bands, and high operation stability. Here, we report a molecular-design strategy. Such a strategy leads to a fast reverse intersystem crossing rate in our designed emitter
h
-BNCO-1 of 1.79×10
5
s
−1
. An OLED exploiting a binary EML with
h
-BNCO-1 achieves ultrapure emission, a maximum external quantum efficiency of over 40% and a mild roll-off of 14% at 1000 cd·m
−2
. Moreover,
h
-BNCO-1 also exhibits promising operational stability in an alternative OLED exploiting a compact binary EML (the lifetime reaching 95% of the initial luminance at 1000 cd m
−2
is ~ 137 h). Here, our work has thus provided a molecular-design strategy for OLEDs with promising comprehensive performance.
Multi-resonance thermally activated delayed fluorescent emitters composed of only period-2 elements are important for achieving comprehensive performances. Here, authors report hybridization of organoboron-nitrogen and carbonyl groups in the emitter to achieve a long device operational stability.
Publisher
Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio
Subject
