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Diurnal humidity cycle driven selective ion transport across clustered polycation membrane.

Yuanyuan ZhaoJu LiuGang LuJinliang ZhangLiyang WanShan PengChao LiYanlei WangMingzhan WangHongyan HeJohn H XinYulong DingShuang Zheng
Published in: Nature communications (2024)
The ability to manipulate the flux of ions across membranes is a key aspect of diverse sectors including water desalination, blood ion monitoring, purification, electrochemical energy conversion and storage. Here we illustrate the potential of using daily changes in environmental humidity as a continuous driving force for generating selective ion flux. Specifically, self-assembled membranes featuring channels composed of polycation clusters are sandwiched between two layers of ionic liquids. One ionic liquid layer is kept isolated from the ambient air, whereas the other is exposed directly to the environment. When in contact with ambient air, the device showcases its capacity to spontaneously produce ion current, with promising power density. This result stems from the moisture content difference of ionic liquid layers across the membrane caused by the ongoing process of moisture absorption/desorption, which instigates selective transmembrane ion flux. Cation flux across the polycation clusters is greatly inhibited because of intensified charge repulsion. However, anions transport across polycation clusters is amplified. Our research underscores the potential of daily cycling humidity as a reliable energy source to trigger ion current and convert it into electrical current.
Keyphrases
  • ionic liquid
  • room temperature
  • air pollution
  • particulate matter
  • physical activity
  • human health
  • risk assessment
  • single molecule
  • high resolution