Cameron M. Cole, Susanna V. Kunz, P. Shaw, C. S. K. Ranasinghe, Thomas Baumann, J. Blinco, P. Sonar, C. Barner‐Kowollik, S. Yambem
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引用次数: 4
摘要
热激活延迟荧光(TADF)材料被广泛研究为有机发光二极管(oled),具有TADF发射层,在不使用重金属配合物的情况下显示出高效率。因此,溶液可处理和可打印的TADF发射器是非常可取的,远离昂贵的真空沉积技术。此外,使用不需要外部主机的发射材料大大简化了制造过程。本文介绍了使用溶液可加工TADF聚合物的oled,该聚合物不需要外部主机。非共轭TADF聚合物具有TADF发射器(4‐(9H‐咔唑‐9‐基)‐2‐(3′‐羟基‐[1,1′‐联苯]‐3‐基)‐异吲哚啉‐1,3‐二酮)作为侧链,以及在非活性聚合物主链上的空穴传递侧链和电子传递侧链。oled的所有有机层都是用溶液加工方法制造的。喷墨印刷发光层的oled与自旋涂层的oled相比,具有相当的最大电流和外量子效率,亮度超过2000 cd m−2。本文探讨的策略是实现自托管可打印TADF oled的可行途径。
Thermally activated delayed fluorescent (TADF) materials are extensively investigated as organic light‐emitting diodes (OLEDs) with TADF emitting layers demonstrating high efficiency without the use of heavy metal complexes. Therefore, solution‐processable and printable TADF emitters are highly desirable, moving away from expensive vacuum deposition techniques. In addition, using emissive materials not requiring an external host simplifies the fabrication process significantly. Herein, OLEDs using a solution‐processable TADF polymer that do not need an external host are introduced. The non‐conjugated TADF polymer features a TADF emitter (4‐(9H‐carbazol‐9‐yl)‐2‐(3′‐hydroxy‐[1,1′‐biphenyl]‐3‐yl)‐isoindoline‐1,3‐dione) as a side chain, as well as a hole‐transporting side chain and an electron‐transporting side chain on an inactive polymer backbone. All organic layers of the OLEDs are fabricated using solution processing methods. The OLEDs with inkjet‐printed emissive layers have comparable maximum current and external quantum efficiency as their spin‐coated counterparts, exceeding luminance of 2000 cd m−2. The herein‐explored strategy is a viable route toward self‐hosted printable TADF OLEDs.
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