Bioinspired and engineered ion-selective membranes toward high-flux and high-selectivity energy devices
Author Identifier (ORCID)
Amir Razmjou: https://orcid.org/0000-0002-3554-5129
Abstract
Nanofluidic membranes with precise ion selectivity and ultrahigh permeability are central to advancing electromembrane technologies for energy generation, storage, water purification, and environmental monitoring. The performance of these systems hinges on the ability of membranes to efficiently and selectively transport ions. However, synthetic ion-selective membranes (ISMs) face a fundamental trade-off: increasing ion selectivity typically reduces permeability, and vice versa. Overcoming this trade-off is essential for realizing next-generation ISMs with enhanced performance. This review summarizes recent progress in addressing the selectivity–permeability trade-off through innovative membrane architectures, advanced fabrication methods, material engineering strategies, and modeling tools that clarify structure–property–performance relationships. Biological ion channels serve as benchmarks, offering ultra-efficient ion transport via precise control of pore size, surface charge, pathway length, and rectification effects. Drawing on these natural systems, we highlight bio-inspired strategies for enhancing synthetic membrane performance. We also discuss the role of ISMs in electrochemical applications and assess remaining challenges in achieving high ion flux without compromising selectivity. Emerging solutions including hybrid membrane systems, advanced nanomaterials, and AI-assisted design present promising pathways forward. The review concludes by outlining future directions that integrate computational modeling with experimental validation to develop efficient, scalable, and sustainable membrane technologies.
Keywords
Electrochemical technologies, ion channels, ion permeability, ion selectivity, ion-selective membranes
Document Type
Journal Article
Date of Publication
2-20-2026
Volume
22
Issue
11
PubMed ID
41653465
Publication Title
Small
Publisher
Wiley
School
Mineral Recovery Research Centre / School of Engineering
Copyright
subscription content
Comments
Tonnah, R. K., Foorginezhad, S., Nyande, B. W., Arshadi, F., Razbin, M., Chai, M., Razmjou, A., & Asadnia, M. (2026). Bioinspired and engineered ion-selective membranes toward high-flux and high-selectivity energy devices. Small, 22(11), e10500. https://doi.org/10.1002/smll.202510500