Structure engineering : extending the length of azaacene derivatives through quinone bridges

Structure engineering : extending the length of azaacene derivatives through quinone bridges

Increasing the length of azaacene derivatives through quinone bridges is very important because these materials could have deep LUMO energy levels and larger overlapping in the solid state, which would have great applications in organic semiconducting devices. Here, two fully characterized large qui...

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Main Authors: Wang, Zilong, Wang, Zongrui, Zhou, Yecheng, Gu, Peiyang, Liu, Guangfeng, Zhao, Kexiang, Nie, Lina, Zeng, Qingsheng, Zhang, Jing, Li, Yongxin, Ganguly, Rakesh, Aratani, Naoki, Huang, Li, Liu, Zheng, Yamada, Hiroko, Hu, Wenping, Zhang, Qichun
Other Authors: School of Materials Science & Engineering
Format: Article
Language:English
Published: 2020
Subjects:
Engineering::Materials
Azaacene Derivatives
Quinone Bridges
Online Access:https://hdl.handle.net/10356/140630
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1406302020-06-01T10:43:38Z Structure engineering : extending the length of azaacene derivatives through quinone bridges Wang, Zilong Wang, Zongrui Zhou, Yecheng Gu, Peiyang Liu, Guangfeng Zhao, Kexiang Nie, Lina Zeng, Qingsheng Zhang, Jing Li, Yongxin Ganguly, Rakesh Aratani, Naoki Huang, Li Liu, Zheng Yamada, Hiroko Hu, Wenping Zhang, Qichun School of Materials Science & Engineering School of Physical and Mathematical Sciences Engineering::Materials Azaacene Derivatives Quinone Bridges Increasing the length of azaacene derivatives through quinone bridges is very important because these materials could have deep LUMO energy levels and larger overlapping in the solid state, which would have great applications in organic semiconducting devices. Here, two fully characterized large quinone-fused azaacenes Hex-CO and Hept-CO prepared through a novel palladium-catalyzed coupling reaction are reported. Our research clearly proved that the quinone unit can be employed as a bridge to extend the molecular conjugation length, increase the molecular overlapping, and engineer the molecular stacking mode. Hex-CO shows lamellar 2-D π-stacking modes, while Hept-CO shows 1-D π-stacking and adopts a 3-D interlocked stacking mode with the adjacent molecular layers vertical to each other. With the deep LUMO energy levels (∼−4.27 eV), Hex-CO and Hept-CO were both demonstrated to be electron-transport layers. Their charge transport properties were investigated through OFETs and theoretical calculations. Due to the different stacking modes, Hex-CO shows a higher electron mobility of 0.22 cm2 V−1 s−1 than Hept-CO (7.5 × 10−3 cm2 V−1 s−1) in a single-crystal-based OFET. Our results provide a new route for structure engineering through extending the azaacene derivatives by quinone bridges, which can be of profound significance in organic electronics. MOE (Min. of Education, S’pore) 2020-06-01T02:50:56Z 2020-06-01T02:50:56Z 2018 Journal Article Wang, Z., Wang, Z., Zhou, Y., Gu, P., Liu, G., Zhao, K., . . . Zhang, Q. (2018). Structure engineering : extending the length of azaacene derivatives through quinone bridges. Journal of Materials Chemistry C, 6(14), 3628-3633. doi:10.1039/c8tc00628h 2050-7526 https://hdl.handle.net/10356/140630 10.1039/c8tc00628h 2-s2.0-85045072914 14 6 3628 3633 en Journal of Materials Chemistry C © 2018 The Royal Society of Chemistry. All rights reserved.
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
topic Engineering::Materials
Azaacene Derivatives
Quinone Bridges
spellingShingle Engineering::Materials
Azaacene Derivatives
Quinone Bridges
Wang, Zilong
Wang, Zongrui
Zhou, Yecheng
Gu, Peiyang
Liu, Guangfeng
Zhao, Kexiang
Nie, Lina
Zeng, Qingsheng
Zhang, Jing
Li, Yongxin
Ganguly, Rakesh
Aratani, Naoki
Huang, Li
Liu, Zheng
Yamada, Hiroko
Hu, Wenping
Zhang, Qichun
Structure engineering : extending the length of azaacene derivatives through quinone bridges
description Increasing the length of azaacene derivatives through quinone bridges is very important because these materials could have deep LUMO energy levels and larger overlapping in the solid state, which would have great applications in organic semiconducting devices. Here, two fully characterized large quinone-fused azaacenes Hex-CO and Hept-CO prepared through a novel palladium-catalyzed coupling reaction are reported. Our research clearly proved that the quinone unit can be employed as a bridge to extend the molecular conjugation length, increase the molecular overlapping, and engineer the molecular stacking mode. Hex-CO shows lamellar 2-D π-stacking modes, while Hept-CO shows 1-D π-stacking and adopts a 3-D interlocked stacking mode with the adjacent molecular layers vertical to each other. With the deep LUMO energy levels (∼−4.27 eV), Hex-CO and Hept-CO were both demonstrated to be electron-transport layers. Their charge transport properties were investigated through OFETs and theoretical calculations. Due to the different stacking modes, Hex-CO shows a higher electron mobility of 0.22 cm2 V−1 s−1 than Hept-CO (7.5 × 10−3 cm2 V−1 s−1) in a single-crystal-based OFET. Our results provide a new route for structure engineering through extending the azaacene derivatives by quinone bridges, which can be of profound significance in organic electronics.
author2 School of Materials Science & Engineering
author_facet School of Materials Science & Engineering
Wang, Zilong
Wang, Zongrui
Zhou, Yecheng
Gu, Peiyang
Liu, Guangfeng
Zhao, Kexiang
Nie, Lina
Zeng, Qingsheng
Zhang, Jing
Li, Yongxin
Ganguly, Rakesh
Aratani, Naoki
Huang, Li
Liu, Zheng
Yamada, Hiroko
Hu, Wenping
Zhang, Qichun
format Article
author Wang, Zilong
Wang, Zongrui
Zhou, Yecheng
Gu, Peiyang
Liu, Guangfeng
Zhao, Kexiang
Nie, Lina
Zeng, Qingsheng
Zhang, Jing
Li, Yongxin
Ganguly, Rakesh
Aratani, Naoki
Huang, Li
Liu, Zheng
Yamada, Hiroko
Hu, Wenping
Zhang, Qichun
author_sort Wang, Zilong
title Structure engineering : extending the length of azaacene derivatives through quinone bridges
title_short Structure engineering : extending the length of azaacene derivatives through quinone bridges
title_full Structure engineering : extending the length of azaacene derivatives through quinone bridges
title_fullStr Structure engineering : extending the length of azaacene derivatives through quinone bridges
title_full_unstemmed Structure engineering : extending the length of azaacene derivatives through quinone bridges
title_sort structure engineering : extending the length of azaacene derivatives through quinone bridges
publishDate 2020
url https://hdl.handle.net/10356/140630
_version_ 1681056926354374656

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