材料科学
离子
膜
聚酰胺
Boosting(机器学习)
能量转换
离子运输机
复合数
浓差极化
光电子学
工作(物理)
化学工程
极化(电化学)
能量转换效率
渗透力
薄膜复合膜
电荷(物理)
渗透
化学物理
纳米技术
复合材料
电导率
对偶(语法数字)
能量(信号处理)
化学
渗透压
高效能源利用
作者
Zifeng Cao,Baohu Wu,Haoyuan Sun,Huiqing Wu,Peiyi Wu
摘要
ABSTRACT Asymmetric ion‐selective membranes show promise for efficient osmotic energy harvesting. Most current asymmetric membranes adopt a bipolar structure to mitigate concentration polarization. However, this approach usually increases transport resistance and compromises ion selectivity. To address these, we rationally designed a dual polyamide thin‐film composite (dPA TFC) membrane via sequential interfacial polymerization (IP). The membrane is composed of two distinct polyamide (PA) layers in situ formed on a macroporous substrate. Through a surfactant‐assisted IP process, an ultrathin inner PA layer with a uniform and negatively charged 3D pore structure was obtained, delivering both high ion selectivity and permeability. Subsequently, a loose outer PA layer featuring a mosaic charge architecture was constructed using protonated porphyrin as a building block. This layer promotes significant unidirectional ion transport and effectively suppresses concentration polarization, while maintaining a high cation selectivity of 0.962. Additionally, the membrane exhibits photo‐responsive behavior, enabling photo‐enhanced osmotic energy conversion and antibacterial activity. As a result, the dPA TFC membrane achieves a high osmotic power density of 13.2 W m −2 under light irradiation. This work provides a design paradigm that overcomes the conventional permeability‐selectivity trade‐off while simultaneously balancing ion concentration polarization suppression with high selectivity, thereby advancing the development of osmotic energy conversion systems.
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