Please use this identifier to cite or link to this item: http://dx.doi.org/10.25673/115507
Title: Proton-conducting membranes from polyphenylenes containing Armstrong’s acid
Author(s): Künzel-Tenner, Andy
Kirsch, ChristophLook up in the Integrated Authority File of the German National Library
Dolynchuk, Oleksandr
Rößner, LeonardLook up in the Integrated Authority File of the German National Library
Wach, Maxime
Kempe, FabianLook up in the Integrated Authority File of the German National Library
Unwerth, Thomas
Lederer, AlbenaLook up in the Integrated Authority File of the German National Library
Sebastiani, DanielLook up in the Integrated Authority File of the German National Library
Armbrüster, MarcLook up in the Integrated Authority File of the German National Library
Sommer, Michael
Issue Date: 2024
Type: Article
Language: English
Abstract: This study demonstrates the use of 1,5-naphthalenedisulfonic acid as a suitable building block for the efficient and economic preparation of alternating sulfonated polyphenylenes with high ion-exchange capacity (IEC) via Suzuki polycondensation. Key to large molar masses is the use of an all-meta-terphenyl comonomer instead of m-phenyl, the latter giving low molar masses and brittle materials. A protection/deprotection strategy for base-stable neopentyl sulfonates is successfully implemented to improve the solubility and molar mass of the polymers. Solution-based deprotection of polyphenylene neopentyl sulfonates at 150 °C in dimethylacetamide eliminates isopentylene quantitatively, resulting in membranes with high IEC (2.93 mequiv/g) and high proton conductivity (σ = 138 mS/cm). Water solubility of these copolymers with high IEC requires thermal cross-linking to prevent their dissolution under operating conditions. By balancing the temperature and time of the cross-linking process, water uptake can be restricted to 50 wt %, retaining an IEC of 2.33 mequiv/g and a conductivity of 85 mS/cm. Chemical stability is addressed by treatment of the membranes under Fenton’s conditions and by considering barrier heights for desulfonation using density functional theory (DFT) calculations. The DFT results suggest that 1,5-disulfonated naphthalenes are at least as stable as sulfonated polyphenylenes against desulfonation.
URI: https://opendata.uni-halle.de//handle/1981185920/117461
http://dx.doi.org/10.25673/115507
Open Access: Open access publication
License: (CC BY 4.0) Creative Commons Attribution 4.0(CC BY 4.0) Creative Commons Attribution 4.0
Journal Title: Macromolecules
Publisher: Soc.
Publisher Place: Washington, DC
Volume: 57
Original Publication: 10.1021/acs.macromol.3c02123
Page Start: 1238
Page End: 1247
Appears in Collections:Open Access Publikationen der MLU