材料科学
光刻
量子点
光电子学
聚合物
胶体
纳米技术
溶解过程
图层(电子)
平版印刷术
发光二极管
二极管
等离子体子
紫外线
量子效率
灵活的显示器
光致发光
兴奋剂
光子学
光学滤波器
半导体
胶体晶体
作者
Jaeyeop Lee,Seon Lee Kwak,Chaegwang Lim,Hyunjun Lee,Woon Ho Jung,Byong Jae Kim,Jisu Han,Kyoungeun Lee,Yeyun Bae,Jiyoon Oh,Hyoung-Jun Kim,Keon Woo Kim,Byeong Guk Jeong,Jaehoon Lim,Do‐Hoon Hwang,Jeongkyun Roh
标识
DOI:10.1002/adfm.202520047
摘要
Abstract There has been considerable progress in colloidal quantum dot light‐emitting diodes (QD‐LEDs) for display applications. However, their commercialization remains challenging, because of the difficulty in achieving high‐resolution, full‐color patterning of quantum dots (QDs) without degrading their optical properties. Direct photolithography has attracted attention, but it often requires complicated ligand‐exchange processes and causes ultraviolet (UV)‐induced QD degradation. Herein, a nondestructive, universal QD patterning method that blends QDs with a photocrosslinkable hole‐transport layer (HTL) polymer, poly(9‐vinylcarbazole), is presented. Upon UV irradiation, the resulting blended films form a robust crosslinked network that encapsulates and protects the QDs, enabling high‐resolution patterning while preserving their optical properties. By employing this strategy to cadmium (Cd)‐based QDs, monochrome resolutions exceeding 10 000 pixels per inch are achieved, without requiring ligand‐exchange steps. Furthermore, incorporating this photocrosslinked blended emissive layer into QD‐LEDs enhances the device performance by suppressing excess electron injection and improving hole injection, leading to a 1.7 fold increase in the external quantum efficiency and a three fold extension of operational lifetimes. Notably, this process can be readily applied to diverse QDs, including Cd‐free variants and other functional nanocrystals, highlighting the broad applicability and commercial potential of this photocrosslinkable QD‐HTL platform for next‐generation display technologies.
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