亮度
材料科学
光电子学
发光二极管
二极管
兴奋剂
电压
电子
光通信
活动层
接口(物质)
量子点
有机发光二极管
图层(电子)
载流子
过程(计算)
量子效率
加密
阈值电压
激光器
激发
LED显示屏
计算机科学
光学
调制(音乐)
自发辐射
逻辑门
亮度
灵活的显示器
电致发光
脉冲宽度调制
晶体管
异质结
光发射
作者
Shuchen Weng,Haonan Wang,Zi-Shan Wang,Cong Zheng,Chenliang Liu,Xiongtu Zhou,Chaoxing Wu,Tailiang Guo,Yongai Zhang
标识
DOI:10.1002/adfm.202520799
摘要
Abstract Quantum‐dot light‐emitting diodes (QLEDs) are attracting attention as next‐generation display devices due to their tunable spectral emission properties, superior color purity, and accessibility to solution processing. However, their efficiency is still limited by the injection and transport imbalances between electrons and holes as charge carriers. In contrast to conventional approaches focusing more on the material and interfacial engineering, including functional layer optimization, interface engineering, or doping strategies, the team designs and fabricates a three‐terminal gate‐tunable QLEDs structure that directly regulates the carrier transport process to bridge the gap between electrons and holes injection and transport, achieving an effective increase in EQE (from 8.33% to 14.98%, a 79.8% improvement) and, at the same time, reaches the maximum brightness of the device much faster than in the absence of a gate presence. Inspired by the specificity of the gate‐tunable brightness response to driving conditions dominated by the gate voltage and hardware parameters, including the thickness of the insulating layer, it is believed that this structure has great potential for applications in dual‐key optical communications and image encryption.
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