Alkaline Stability Evaluation of Polymerizable Hexyl-Tethered Ammonium Cations

One of the important challenges in designing robust alkaline anion exchange membranes is the difficulty associated with the chemical stability of covalently bound cationic units. Here, a systematic study exploring alkaline stabilities of polymerizable hexyltrimethylammonium cations is presented, where the hexyl chain is linked to a phenyl ring through a direct carbon-carbon, phenyl ether, or benzyl ether functionality. For this work, small molecule model compounds, styrenic monomer analogs, and their homopolymers are synthesized. Alkaline stabilities of the small molecule cations and their homopolymers are compared to alkaline stability of benzyltrimethylammonium (BTMA) cation and its homopolymer poly(BTMA), respectively. All the hexyl-tethered cations and their homopolymers are significantly more stable under strongly alkaline conditions (2 m KOD at 80 degrees C). Moreover, ether-linked cations show comparable stability to the direct carbon-carbon linked cation. Via H-1 NMR analyses, possible degradation mechanisms are investigated for each small molecule cation. Findings of this study strongly suggest that the alkaline stability is dictated by the steric hindrance around the beta-hydrogen. This study expands beyond the limits of general knowledge on alkaline stability of alkyl-tethered ammonium cations via the Hofmann elimination route, highlights important design parameters for stable ammonium cations, and demonstrates accessible directly polymerizable alkaline stable ammonium cations.

Automated summary

This study presents a systematic exploration of the alkaline stabilities of polymerizable hexyltrimethylammonium cations, finding that the hexyl-tethered cations are more stable under strongly alkaline conditions compared to benzyltrimethylammonium (BTMA). The findings also demonstrate that ether-linked cations show comparable stability to directly carbon-carbon linked cations, with possible degradation mechanisms investigated through H-1 NMR analyses. The research highlights the importance of steric hindrance in controlling alkaline stability and expands knowledge on stable ammonium cations.