膜
纳米颗粒
化学
无机化学
离子交换
选择性
离子运输机
离子
扩散
磷酸盐
锰
氯化物
化学工程
材料科学
纳米技术
催化作用
有机化学
工程类
物理
热力学
生物化学
作者
Arpita Iddya,Piotr Zarzycki,Ryan Kingsbury,Chia Miang Khor,Shengcun Ma,J. Wang,Ian Wheeldon,Zhiyong Jason Ren,Eric M.V. Hoek,David Jassby
标识
DOI:10.1038/s41565-022-01209-x
摘要
Specific-ion selectivity is a highly desirable feature for the next generation of membranes. However, existing membranes rely on differences in charge, size and hydration energy, which limits their ability to target individual ion species. Here we demonstrate a nanocomposite ion-exchange membrane material that enables a reverse-selective transport mechanism that can selectively pass a single ion species. We demonstrate this transport mechanism with phosphate ions selectively transporting across negatively charged cation exchange membranes. Selective transport is enabled by the in situ growth of hydrous manganese oxide nanoparticles throughout a cation exchange membrane that provide a diffusion pathway via phosphate-specific, reversible outer-sphere interactions. On incorporating the hydrous manganese oxide nanoparticles, the membrane's phosphate flux increased by a factor of 27 over an unmodified cation exchange membrane, and the selectivity of phosphorous over sulfate, nitrate and chloride reaches 47, 100 and 20, respectively. By pairing ion-specific outer-sphere interactions between the target ions and appropriate nanoparticles, these nanocomposite ion-exchange materials can, in principle, achieve selective transport for a range of ions. Cation exchange membranes embedded with MnO2 nanoparticles form selective outer-sphere complexes with phosphate ions imparting an extremely selective permeation pathway.
科研通智能强力驱动
Strongly Powered by AbleSci AI