Molecular-Scale Asymmetry Nanochannels for High-Efficiency Osmotic Energy Generation

化学 不对称 比例(比率) 化学工程 化学物理 纳米技术 量子力学 物理 工程类 材料科学
作者
Chao Liu,Caichao Ye,Jiali Wang,Ting Yang,Anqi Ni,Tianning Zhang,Kunpeng Mao,Long Chen,Shijian Wang,Jingwen Sun,Wenqing Zhang,Xin Wang,Jianfei Che,Pan Xiong,Guoxiu Wang,Junwu Zhu
出处
期刊:Journal of the American Chemical Society [American Chemical Society]
卷期号:147 (32): 29179-29191 被引量:5
标识
DOI:10.1021/jacs.5c08016
摘要

Osmotic power, as an example of iontronics, can convert an ion gradient to electrical energy by the membrane-based reverse electrodialysis technique. However, its efficiency in harvesting osmotic energy is mostly dependent on ion permeability and selectivity during transmembrane diffusion. The two-dimensional (2D) heterogeneous interface establishes molecular-scale asymmetric structure and charge that is expected to exert a crucial effect on the ion permeability and selectivity but remains unexplored. Here, we designed a 2D nanofluidic membrane with molecular-level asymmetric channels that can achieve high cation selectivity while maintaining outstanding ion conductivity. When applied to osmotic energy generators, this membrane can exhibit a high cation selectivity coefficient of 0.985 and a superior energy conversion efficiency of up to 47.1%, coupled with an excellent output power density of over 20 W m-2 in mixing the artificial seawater and river water. The Na+ ions transport through a 2D heterostructured membrane via an interface-induced contiguous ion adsorption-diffusion mechanism is uncovered. The asymmetric pore structure and negative charge distribution enable highly selective adsorption of Na+ ions and subsequently fast transport in the molecular-scale asymmetric nanochannels. This work provides an in-depth understanding of ion transport in asymmetric nanochannels and further inspires their applications in other advanced energy-harvesting devices.
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