Highly polarized emission from organic single-crystal light-emitting devices with a polarization ratio of 176

Polarized light emission from organic light-emitting devices (OLEDs) is of considerable current interest because of their great potential in various optical and optoelectronic devices. Utilizing materials with aligned molecular orientation is a simple and promising way to realize highly polarized OL...

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Published inOptica Vol. 9; no. 1; p. 121
Main Authors An, Ming-Hui, Ding, Ran, Zhang, Xu-Lin, Chen, Shuo-Nan, Wang, Ya-Nan, Ye, Gao-Da, Zhu, Qin-Cheng, Chen, Nian-Ke, Liu, Yu, Feng, Jing, Sun, Hong-Bo
Format Journal Article
LanguageEnglish
Published 20.01.2022
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Abstract Polarized light emission from organic light-emitting devices (OLEDs) is of considerable current interest because of their great potential in various optical and optoelectronic devices. Utilizing materials with aligned molecular orientation is a simple and promising way to realize highly polarized OLEDs; however, both the polarization ratio and efficiency are still far from the requirements for practical applications. Organic single crystals with inherent anisotropic properties induced by their long-range periodic order are ideal candidates for intrinsically polarized emission. Herein, the intrinsic polarization has been dramatically amplified by constructing a microcavity structure in organic single-crystal OLEDs to effectively couple microcavity resonance to polarized light. A high polarization ratio of 176 has been achieved from the polarized OLEDs. Moreover, highly aligned single-crystalline molecules with small tilted orientation angles to the crystal surface result in a high outcoupling efficiency for surface-emitting crystal OLEDs. A maximum luminance of 6122 c d / m 2 and current efficiency of 1.86 cd/A were achieved, which are among the best performances for crystal OLEDs. This work may lead to a new strategy for simultaneously enhancing the polarization ratio and efficiency of polarized OLEDs and promote their development in various optical and optoelectronic applications.
AbstractList Polarized light emission from organic light-emitting devices (OLEDs) is of considerable current interest because of their great potential in various optical and optoelectronic devices. Utilizing materials with aligned molecular orientation is a simple and promising way to realize highly polarized OLEDs; however, both the polarization ratio and efficiency are still far from the requirements for practical applications. Organic single crystals with inherent anisotropic properties induced by their long-range periodic order are ideal candidates for intrinsically polarized emission. Herein, the intrinsic polarization has been dramatically amplified by constructing a microcavity structure in organic single-crystal OLEDs to effectively couple microcavity resonance to polarized light. A high polarization ratio of 176 has been achieved from the polarized OLEDs. Moreover, highly aligned single-crystalline molecules with small tilted orientation angles to the crystal surface result in a high outcoupling efficiency for surface-emitting crystal OLEDs. A maximum luminance of 6122 c d / m 2 and current efficiency of 1.86 cd/A were achieved, which are among the best performances for crystal OLEDs. This work may lead to a new strategy for simultaneously enhancing the polarization ratio and efficiency of polarized OLEDs and promote their development in various optical and optoelectronic applications.
Author Ye, Gao-Da
Liu, Yu
Zhang, Xu-Lin
Feng, Jing
Sun, Hong-Bo
Ding, Ran
Wang, Ya-Nan
An, Ming-Hui
Chen, Nian-Ke
Zhu, Qin-Cheng
Chen, Shuo-Nan
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  ident: optica-9-1-121-R11
  publication-title: Europhys. Lett.
  doi: 10.1209/0295-5075/32/6/011
– volume: 14
  start-page: 1900341
  year: 2020
  ident: optica-9-1-121-R13
  publication-title: Laser Photon. Rev.
  doi: 10.1002/lpor.201900341
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Snippet Polarized light emission from organic light-emitting devices (OLEDs) is of considerable current interest because of their great potential in various optical...
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StartPage 121
Title Highly polarized emission from organic single-crystal light-emitting devices with a polarization ratio of 176
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