Asymmetrically Functionalized Electron‐Deficient π‐Conjugated System for Printed Single‐Crystalline Organic Electronics

Asymmetrically Functionalized Electron‐Deficient π‐Conjugated System for Printed Single‐Crystalline Organic Electronics

Abstract Large‐area single‐crystalline thin films of n‐type organic semiconductors (OSCs) fabricated via solution‐processed techniques are urgently demanded for high‐end electronics. However, the lack of molecular designs that concomitantly offer excellent charge‐carrier transport, solution‐processa...

Full description

Saved in:
Bibliographic Details
Main Authors: Craig P. Yu, Shohei Kumagai, Michitsuna Tsutsumi, Tadanori Kurosawa, Hiroyuki Ishii, Go Watanabe, Daisuke Hashizume, Hiroki Sugiura, Yukio Tani, Toshihiro Ise, Tetsuya Watanabe, Hiroyasu Sato, Jun Takeya, Toshihiro Okamoto
Format: Article
Language:English
Published: Wiley 2023-10-01
Series:Advanced Science
Subjects:
asymmetric n‐type organic semiconductors
large‐area single‐crystalline thin films
molecular design
nitrogen‐containing π‐electron systems
organic field‐effect transistors
Online Access:https://doi.org/10.1002/advs.202207440
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Abstract Large‐area single‐crystalline thin films of n‐type organic semiconductors (OSCs) fabricated via solution‐processed techniques are urgently demanded for high‐end electronics. However, the lack of molecular designs that concomitantly offer excellent charge‐carrier transport, solution‐processability, and chemical/thermal robustness for n‐type OSCs limits the understanding of fundamental charge‐transport properties and impedes the realization of large‐area electronics. The benzo[de]isoquinolino[1,8‐gh]quinolinetetracarboxylic diimide (BQQDI) π‐electron system with phenethyl substituents (PhC2–BQQDI) demonstrates high electron mobility and robustness but its strong aggregation results in unsatisfactory solubility and solution‐processability. In this work, an asymmetric molecular design approach is reported that harnesses the favorable charge transport of PhC2–BQQDI, while introducing alkyl chains to improve the solubility and solution‐processability. An effective synthetic strategy is developed to obtain the target asymmetric BQQDI (PhC2–BQQDI–Cn). Interestingly, linear alkyl chains of PhC2–BQQDI–Cn (n = 5–7) exhibit an unusual molecular mimicry geometry with a gauche conformation and resilience to dynamic disorders. Asymmetric PhC2–BQQDI–C5 demonstrates excellent electron mobility and centimeter‐scale continuous single‐crystalline thin films, which are two orders of magnitude larger than that of PhC2–BQQDI, allowing for the investigation of electron transport anisotropy and applicable electronics.
ISSN:2198-3844

Similar Items