Improving Performance of Organic Light-emitting Diodes by Tuning Molecular Orientation in Hole Transport Layer
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Device Fabrication and Physics|更新时间:2021-05-20
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Improving Performance of Organic Light-emitting Diodes by Tuning Molecular Orientation in Hole Transport Layer
Chinese Journal of LuminescenceVol. 42, Issue 5, Pages: 691-699(2021)
作者机构:
1.聊城大学 物理科学与信息工程学院,山东 聊城 252059
2.山东省光通信科学与技术重点实验室,山东 聊城 252059
作者简介:
基金信息:
National Natural Science Foundation of China(61775089);Natural Science Foundation of Shandong Province(ZR2017BF009);Project of Liaocheng University(318011904;318051650)
Dong-yue CUI, Shuai WANG, Shu-hong LI, et al. Improving Performance of Organic Light-emitting Diodes by Tuning Molecular Orientation in Hole Transport Layer. [J]. Chinese Journal of Luminescence 42(5):691-699(2021)
DOI:
Dong-yue CUI, Shuai WANG, Shu-hong LI, et al. Improving Performance of Organic Light-emitting Diodes by Tuning Molecular Orientation in Hole Transport Layer. [J]. Chinese Journal of Luminescence 42(5):691-699(2021) DOI: 10.37188/CJL.20210046.
Improving Performance of Organic Light-emitting Diodes by Tuning Molecular Orientation in Hole Transport Layer
The performance improvement of organic light-emitting diodes(OLED) devices has always been one of the research topics in the field of organic electroluminescence. Optimization of carrier balance in OLED devices is a critical method to improve the performance of OLED devices. However
it is often neglected to optimize the carrier balance in the OLEDs by tuning the molecular orientation in the hole transport layer or electron transport layer. In this paper
the molecular orientation in the hole transport layer was altered by heat annealing at different temperatures to study the influence of molecular orientation on the hole mobility and the performance of OLED device. It showed that the proportion of molecules with vertical orientation in the hole transport layer was increased with the rise of annealing temperature
which promoted the increase of the hole mobility. When the hole transport layers with different molecular orientations were applied to OLED devices
the effect of the carrier balance factor on the device performance can be clearly observed.
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