Recent advances in organic near-infrared photodiodes

Solution-processable organic photodiodes compensate well for the shortages of the traditional inorganic photodetectors in terms of their unique features, such as rich in varieties, low-cost manufacturing, light weight, high flexibility, and large-area scalability. Owing to the tunable optoelectronic...

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Published inJournal of materials chemistry. C, Materials for optical and electronic devices Vol. 6; no. 14; pp. 3499 - 3513
Main Authors Liu, Xiaodong, Lin, Yiwei, Liao, Yingjie, Wu, Jiazun, Zheng, Yonghao
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 2018
Subjects
Charge efficiency
Charge transfer
Dark current
Narrowband
Optoelectronics
Organic materials
Photodiodes
Quantum efficiency
Shortages
Thickness
Weight reduction
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Summary:Solution-processable organic photodiodes compensate well for the shortages of the traditional inorganic photodetectors in terms of their unique features, such as rich in varieties, low-cost manufacturing, light weight, high flexibility, and large-area scalability. Owing to the tunable optoelectronic properties of organic materials, both panchromatic and narrowband organic photodiodes have been achieved. In this review, we provide a comprehensive overview of the recent progress of organic near-infrared (NIR) photodiodes, mainly focusing on diverse device architectures toward superior performance. The key to achieving a high specific detectivity is a high responsivity while keeping dark current low. Interfacial engineering plays a critical role in suppressing the dark current, and has been identified as an essential approach for maximizing detectivity of organic photodiodes. Besides, optimization of photoactive layer thickness and morphology is also highly desirable. As to narrowband organic NIR photodiodes, we highlight three primary strategies: (i) the use of truly narrowband absorbers; (ii) the manipulation of internal quantum efficiency via charge collection narrowing; and (iii) the incorporation of a resonant optical microcavity structure to exploit charge-transfer absorption. The latter two creative approaches allow for response tuning by simply adjusting the thickness of photoactive layer and cavity, respectively. Both broadband and narrowband organic photodetectors can be realized due to the easily tunable optical/electronic properties of organic semiconductors.
Bibliography:Xiaodong Liu has been a Lecturer at University of Electronic Science and Technology of China (UESTC) since 2016. He received his BS (2008) and PhD (2013) degrees from Beijing Jiaotong University under the supervision of Prof. Xurong Xu. During his PhD studies (2010-2012), he was a visiting PhD student in Prof. L. Jay Guo's group at University of Michigan, Ann Arbor. After graduation, he joined Prof. Yongfang Li's group at Soochow University as a postdoctoral fellow. His research interests include organic solar cells, perovskite solar cells and organic photodetectors.
Yiwei Lin obtained a BS degree from University of Electronic Science and Technology of China (UESTC) in 2017. Currently, he is pursuing his MS degree at UESTC under the supervision of Prof. Yonghao Zheng. His research interests include organic photodetectors and organic solar cells.
Jiazun Wu received his BS degree from University of Electronic Science and Technology of China (UESTC) in 2016. He is currently a graduate student pursuing a MS degree at UESTC under the supervision of Prof. Yonghao Zheng. His research interests focus on panchromatic organic photodetectors and organic solar cells.
YingJie Liao obtained his BS degree from China Three Gorges University in 2017. He is currently pursuing a MS degree under the supervision of Prof. Yonghao Zheng at University of Electronic Science and Technology of China (UESTC). His research interests are fabrication of large-area organic photodetectors and organic solar cells.
Yonghao Zheng has been a Professor at University of Electronic Science and Technology of China (UESTC) since 2016. He received MChem (2008) and PhD (2011) degrees from Durham University, where the dissertation work was done under the supervision of Prof. Martin R. Bryce. He spent two periods of time (2012-2014 and 2016) in Prof. Fred Wudl's group at University of California Santa Barbara as a postdoctoral researcher on the project of developing novel stable radicals for organic electronics. In 2015, he moved to Rice University as a postdoctoral researcher in Prof. James M. Tour's group for the project of enhanced oil recovery using dual-functional nanoparticles. Currently he is interested in the conjugated near-infrared responsive materials as well as the design and characterization of stable radicals.
ISSN:2050-7526
2050-7534
DOI:10.1039/c7tc05042a