纳米流体学
材料科学
离子
纳米技术
选择性
分子动力学
纳米尺度
离子运输机
离子通道
功率密度
纳米-
海水淡化
纳米材料
膜
表面改性
密度泛函理论
化学物理
生物分子
作者
Li Fu,Jinhua Cai,Zidi Yan,Yongchao Qian,Haoyang Ling,Ke Li,Weiwen Xin,Xuanze Li,Wenxiong Shi,Xiang‐Yu Kong,Zhen Zhang,Liping Jiang,Liping Wen
标识
DOI:10.1002/adfm.202530378
摘要
ABSTRACT Nanofluidic channels provide an ideal platform for mimicking the remarkable ion selectivity and permeability of biological ion channels, but current architectures are limited by mismatched pore dimensions, low surface charge, and insufficient functionalization, resulting in subpar ion selectivity and flux. Here, we present rationally designed covalent organic framework (COF) nanofluidics with dual‐confinement channels. By precisely modulating the building block length (from 0.58 to 1.22 nm) and spatially programmable functional group density (from −0.13 to −0.79 µC cm −2 ), we synergistically integrate geometric confinement with affinity interactions to tailor the channel microenvironments. The optimized COF nanofluidics achieved exceptional cation selectivity, enhanced from 0.80 to 0.95, while maintaining high ion throughput that increased from 1.93 × 10 14 to 5.12 × 10 14 ions s −1 . As a result, the COF nanofluidics‐based generator delivers an impressive output power density of 11.3 W m −2 by using natural seawater, capable of continuously powering various electronics. Molecular dynamics simulations reveal the dual‐confinement COF nanofluidics with nanoscale channel geometry and strong affinity interactions facilitate an ion‐hopping process that boosts ion selectivity by 4‐fold and ion throughput by 2.5‐fold compared to unoptimized counterparts. This work provides design principles for developing dual‐confinement nanofluidics, showing potential in desalination and ion separation.
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