Development of a new class of stable and adaptable free-standing fibre mats with high room-temperature hydroxide-ion conductivity-Reference-Cited by-同舟云学术

Development of a new class of stable and adaptable free-standing fibre mats with high room-temperature hydroxide-ion conductivity

Published:2024-02-23 Issue: Volume: Page:
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Author:

Szilagyi Petra¹,Herou Servann²,Kasongo-Ntumba Pauline³,Periasamy Arun³,King James³,Doszczeczko Szymon³,Bushby Andrew³,Sobrido Ana³,Titirici Maria-Magdalena²,McVea Molly³

Affiliation:

1. University of Oslo

2. Imperial College London

3. Queen Mary University of London

Abstract

Abstract For alkaline anion-exchange membrane electrolysers and fuel cells to become a technological reality, hydroxide-ion (OH-) conducting membranes that are flexible, robust, affording high OH- conductivity, and synthesised in a low-cost and scalable way must be developed. In this paper, we engineer a stable, self-supporting, and flexible fibre mat using a low-cost ZIF-8 metal-organic framework composited with ionic liquid tetrabutylammonium hydroxide and widely used polyacrylonitrile as polymeric backbone. We obtain mats with a high intrinsic OH- conductivity for a metal-organic framework-based material already at room temperature, without added ion-conductor polymers. This approach will contribute to the development of low-cost and tuneable ion-conducting membranes.

Publisher

Research Square Platform LLC

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