Asymmetric Side-Chain Engineering In Semiconducting Polymers: A Platform For Greener Processing and Post-Functionalization of Organic Electronics

Authors

Madison Mooney, University of Windsor
Audithya Nyayachavadi, University of Windsor
Angela Awada, University of Windsor
Ekaterini Iakovidis, University of Windsor
Yunfei Wang, University of Southern MississippiFollow
Mei-Nung Chen, National Taiwan University of Science and Technology
Yuzi Liu, Argonne National Laboratory
Jie Xu, Argonne National LaboratoryFollow
Yu-Cheng Chiu, National Taiwan University of Science and TechnologyFollow
Xiaodan Gu, University of Southern MississippiFollow
Simon Rondeau-Gagné, University of WindsorFollow

Document Type

Article

Publication Date

2-7-2023

Abstract

Organic semiconducting polymers are a powerful platform for the design of next-generation technologies due to their excellent optoelectronic properties and solution processability, allowing access to low-cost and scalable manufacturing techniques such as spin-coating, slot-die coating and roll-to-roll printing. However, their extended π-conjugation results in low solubility, requiring the use of toxic halogenated solvents to generate thin films and devices. Furthermore, accessible post-functionalization of semiconductors toward the development of multifunctional devices and sensors remains a challenge due to limited solid-state chemistry for alkyl side chains. In this work, an asymmetric side-chain engineering approach was used to introduce terminal hydroxyl moieties alongside traditional solubilizing branched alkyl chains into an isoindigo-based polymer. The hydroxyl moieties led to significantly improved processability in alcohol-based solvents without sacrificing electronic performance in thin film organic field-effect transistors. Solid state morphologies of the thin films processed from both alcohol-based and traditional halogenated solvents were further characterized using atomic force microscopy and grazing incidence wide angle X-ray scattering. Additionally, Cryo-EM was utilized in order to characterize the role of asymmetric side-chain functionality in solution state aggregation. The versatility of this design was further probed using fluorescein isothiocyanate to directly functionalize the asymmetric polymer in thin film. This facile solid-state post-functionalization further demonstrates asymmetric side-chain engineering to be a viable approach toward the development of sustainably manufactured multifunctional electronics.

Publication Title

Polymer Chemistry

Volume

14

Issue

5

First Page

562

Last Page

572

Recommended Citation

Mooney, M., Nyayachavadi, A., Awada, A., Iakovidis, E., Wang, Y., Chen, M., Liu, Y., Xu, J., Chiu, Y., Gu, X., Rondeau-Gagné, S. (2023). Asymmetric Side-Chain Engineering In Semiconducting Polymers: A Platform For Greener Processing and Post-Functionalization of Organic Electronics. Polymer Chemistry, 14(5), 562-572.
Available at: https://aquila.usm.edu/fac_pubs/21683