Large-area, self-healing block copolymer membranes for energy conversion
Sproncken, Christian C. M. and Liu, Peng and Monney, Justin and Fall, William S. and Pierucci, Carolina and Scholten, Philip B. V. and Van Bueren, Brian and Penedo, Marcos and Fantner, Georg Ernest and Wensink, Henricus H. and Steiner, Ullrich and Weder, Christoph and Bruns, Nico and Mayer, Michael and Ianiro, Alessandro (2024) Large-area, self-healing block copolymer membranes for energy conversion. Nature, 630 (8018). pp. 866-871. 12. ISSN 0028-0836 (https://doi.org/10.1038/s41586-024-07481-2)
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Abstract
Membranes are widely used for separation processes in applications such as water desalination, batteries and dialysis, and are crucial in key sectors of our economy and society 1. The majority of technologically exploited membranes are based on solid polymers and function as passive barriers, whose transport characteristics are governed by their chemical composition and nanostructure. Although such membranes are ubiquitous, it has proved challenging to maximize selectivity and permeability independently, leading to trade-offs between these pertinent characteristics 2. Self-assembled biological membranes, in which barrier and transport functions are decoupled 3,4, provide the inspiration to address this problem 5,6. Here we introduce a self-assembly strategy that uses the interface of an aqueous two-phase system to template and stabilize molecularly thin (approximately 35 nm) biomimetic block copolymer bilayers of scalable area that can exceed 10 cm 2 without defects. These membranes are self-healing, and their barrier function against the passage of ions (specific resistance of approximately 1 MΩ cm 2) approaches that of phospholipid membranes. The fluidity of these membranes enables straightforward functionalization with molecular carriers that shuttle potassium ions down a concentration gradient with exquisite selectivity over sodium ions. This ion selectivity enables the generation of electric power from equimolar solutions of NaCl and KCl in devices that mimic the electric organ of electric rays.
ORCID iDs
Sproncken, Christian C. M., Liu, Peng, Monney, Justin, Fall, William S., Pierucci, Carolina, Scholten, Philip B. V., Van Bueren, Brian, Penedo, Marcos, Fantner, Georg Ernest, Wensink, Henricus H., Steiner, Ullrich, Weder, Christoph, Bruns, Nico ORCID: https://orcid.org/0000-0001-6199-9995, Mayer, Michael and Ianiro, Alessandro;-
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Item type: Article ID code: 89609 Dates: DateEvent27 June 2024Published5 June 2024Published Online29 April 2024Accepted13 April 2023SubmittedSubjects: Science > Chemistry
Science > Natural history > BiologyDepartment: Faculty of Science > Pure and Applied Chemistry Depositing user: Pure Administrator Date deposited: 14 Jun 2024 15:10 Last modified: 12 Dec 2024 15:31 Related URLs: URI: https://strathprints.strath.ac.uk/id/eprint/89609