Asymmetric Two-Dimensional Nanomembranes for Salinity Gradient Energy Conversion

Journal Article

Title: Asymmetric Two-Dimensional Nanomembranes for Salinity Gradient Energy Conversion

Author:

Kim, S.; Choi, H.; Yeom, J.; Kim, T.; Kim, T.; Han, J.; Won, J.; Lee, M.; Kim, H.; Bae, J.; Kim, B.; Lim, G. ; Bisquert, J.; Shim, W.

Publication Date:

January 5, 2026

Journal:

Nano Letters

Volume:

Issue:

Pages:

579–588

Publisher:

American Chemical Society

Affiliation:

Yonsei University, Polytechnic University of Valencia (Universitat Politècnica de València)

Technology:

Salinity Gradient

Engineering:

Performance, Power Take Off

Language:

English

Document Access

Website:

External Link

Citation

APA
BibTex
RIS

Kim, S.; Choi, H.; Yeom, J.; Kim, T.; Kim, T.; Han, J.; Won, J.; Lee, M.; Kim, H.; Bae, J.; Kim, B.; Lim, G. ; Bisquert, J.; Shim, W. (2026). Asymmetric Two-Dimensional Nanomembranes for Salinity Gradient Energy Conversion. Nano Letters, 26(1), 579–588. https://doi.org/10.1021/acs.nanolett.5c05727

@article{Kim-2026-,
author = {Kim, S and Choi, H and Yeom, J and Kim, T and Kim, T and Han, J and Won, J and Lee, M and Kim, H and Bae, J and Kim, B and Lim, G and Bisquert, J and Shim, W},
title = {Asymmetric Two-Dimensional Nanomembranes for Salinity Gradient Energy Conversion},
journal = {Nano Letters},
year = {2026},
month = {jan},
publisher = {American Chemical Society},
volume = {26},
number = {1},
pages = {579--588},
doi = {10.1021/acs.nanolett.5c05727},
url = {https://pubs.acs.org/doi/full/10.1021/acs.nanolett.5c05727},
keywords = {Salinity Gradient, Performance, Power Take Off},
}

Export Citation to BibTex

TY - JOUR
TI - Asymmetric Two-Dimensional Nanomembranes for Salinity Gradient Energy Conversion
AU - Kim, S
AU - Choi, H
AU - Yeom, J
AU - Kim, T
AU - Kim, T
AU - Han, J
AU - Won, J
AU - Lee, M
AU - Kim, H
AU - Bae, J
AU - Kim, B
AU - Lim, G
AU - Bisquert, J
AU - Shim, W
T2 - Nano Letters
AB - Salinity gradient energy offers a ubiquitous, renewable power source but remains inhibited by the trade-off between the ion selectivity and permeability of the membrane, which limits the diffusion potential and ionic current, thus restricting the output power. We designed a membrane with millimeter-scale lateral channels with angstrom height and unipolar asymmetry to overcome these constraints. By applying a localized spark reaction to vermiculite films, we engineered a robust monolithic asymmetric architecture with an enhanced ion selectivity (95.1% Na+) and rectification ratio (R ≈ 10). In modules of 900 cells (30 devices), these membranes sustained power densities of >5.0 W/m2, sufficient to charge smartphones and tablets with minimal performance losses. Our platform addresses long-standing performance and scalability barriers in salinity-gradient energy conversion, providing a pathway toward practical, high-power blue energy devices.
DA - 2026/01//
PY - 2026
PB - American Chemical Society
VL - 26
IS - 1
SP - 579–588
UR - https://pubs.acs.org/doi/full/10.1021/acs.nanolett.5c05727
DO - 10.1021/acs.nanolett.5c05727
LA - English
KW - Salinity Gradient
KW - Performance
KW - Power Take Off
ER -

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Abstract

Salinity gradient energy offers a ubiquitous, renewable power source but remains inhibited by the trade-off between the ion selectivity and permeability of the membrane, which limits the diffusion potential and ionic current, thus restricting the output power. We designed a membrane with millimeter-scale lateral channels with angstrom height and unipolar asymmetry to overcome these constraints. By applying a localized spark reaction to vermiculite films, we engineered a robust monolithic asymmetric architecture with an enhanced ion selectivity (95.1% Na⁺) and rectification ratio (R ≈ 10). In modules of 900 cells (30 devices), these membranes sustained power densities of >5.0 W/m², sufficient to charge smartphones and tablets with minimal performance losses. Our platform addresses long-standing performance and scalability barriers in salinity-gradient energy conversion, providing a pathway toward practical, high-power blue energy devices.