Journal
ANGEWANDTE CHEMIE-INTERNATIONAL EDITION
Volume 62, Issue 26, Pages -Publisher
WILEY-V C H VERLAG GMBH
DOI: 10.1002/anie.202303582
Keywords
Ion Transport; Ion-Selective Membrane; Nanofluidics; Nanopore; Salinity Gradient Power
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The design of ion-selective membranes is crucial for efficient reverse electrodialysis-based osmotic power conversion. However, the tradeoff between ion selectivity and ion permeability in existing porous membranes limits power generation efficiency. Therefore, we provide simple guidelines based on ion transport principles in nanofluidics to enhance osmotic power conversion. Additionally, we discuss strategies for optimizing membrane performance by analyzing various material parameters and outline future directions for maximizing osmotic power conversion efficiency through membrane design.
The design of ion-selective membranes is the key towards efficient reverse electrodialysis-based osmotic power conversion. The tradeoff between ion selectivity (output voltage) and ion permeability (output current) in existing porous membranes, however, limits the upgradation of power generation efficiency for practical applications. Thus, we provide the simple guidelines based on fundamentals of ion transport in nanofluidics for promoting osmotic power conversion. In addition, we discuss strategies for optimizing membrane performance through analysis of various material parameters in membrane design, such as pore size, surface charge, pore density, membrane thickness, ion pathway, pore order, and ionic diode effect. Lastly, a perspective on the future directions of membrane design to further maximize the efficiency of osmotic power conversion is outlined.
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