TY - JOUR
T1 - Selective ion transport through hydrated micropores in polymer membranes
AU - Wang, Anqi
AU - Breakwell, Charlotte
AU - Foglia, Fabrizia
AU - Tan, Rui
AU - Lovell, Louie
AU - Wei, Xiaochu
AU - Wong, Toby
AU - Meng, Naiqi
AU - Li, Haodong
AU - Seel, Andrew
AU - Sarter, Mona
AU - Smith, Keenan
AU - Alvarez-Fernandez, Alberto
AU - Furedi, Mate
AU - Guldin, Stefan
AU - Britton, Melanie M
AU - McKeown, Neil B
AU - Jelfs, Kim E
AU - Song, Qilei
N1 - © 2024. The Author(s).
PY - 2024/11/6
Y1 - 2024/11/6
N2 - Ion-conducting polymer membranes are essential in many separation processes and electrochemical devices, including electrodialysis
1, redox flow batteries
2, fuel cells
3 and electrolysers
4,5. Controlling ion transport and selectivity in these membranes largely hinges on the manipulation of pore size. Although membrane pore structures can be designed in the dry state
6, they are redefined upon hydration owing to swelling in electrolyte solutions. Strategies to control pore hydration and a deeper understanding of pore structure evolution are vital for accurate pore size tuning. Here we report polymer membranes containing pendant groups of varying hydrophobicity, strategically positioned near charged groups to regulate their hydration capacity and pore swelling. Modulation of the hydrated micropore size (less than two nanometres) enables direct control over water and ion transport across broad length scales, as quantified by spectroscopic and computational methods. Ion selectivity improves in hydration-restrained pores created by more hydrophobic pendant groups. These highly interconnected ion transport channels, with tuned pore gate sizes, show higher ionic conductivity and orders-of-magnitude lower permeation rates of redox-active species compared with conventional membranes, enabling stable cycling of energy-dense aqueous organic redox flow batteries. This pore size tailoring approach provides a promising avenue to membranes with precisely controlled ionic and molecular transport functions.
AB - Ion-conducting polymer membranes are essential in many separation processes and electrochemical devices, including electrodialysis
1, redox flow batteries
2, fuel cells
3 and electrolysers
4,5. Controlling ion transport and selectivity in these membranes largely hinges on the manipulation of pore size. Although membrane pore structures can be designed in the dry state
6, they are redefined upon hydration owing to swelling in electrolyte solutions. Strategies to control pore hydration and a deeper understanding of pore structure evolution are vital for accurate pore size tuning. Here we report polymer membranes containing pendant groups of varying hydrophobicity, strategically positioned near charged groups to regulate their hydration capacity and pore swelling. Modulation of the hydrated micropore size (less than two nanometres) enables direct control over water and ion transport across broad length scales, as quantified by spectroscopic and computational methods. Ion selectivity improves in hydration-restrained pores created by more hydrophobic pendant groups. These highly interconnected ion transport channels, with tuned pore gate sizes, show higher ionic conductivity and orders-of-magnitude lower permeation rates of redox-active species compared with conventional membranes, enabling stable cycling of energy-dense aqueous organic redox flow batteries. This pore size tailoring approach provides a promising avenue to membranes with precisely controlled ionic and molecular transport functions.
U2 - 10.1038/s41586-024-08140-2
DO - 10.1038/s41586-024-08140-2
M3 - Article
C2 - 39506120
SN - 0028-0836
JO - Nature
JF - Nature
ER -