材料科学
膜
离子
层状结构
能量转换效率
渗透力
反向电渗析
纳米技术
能量转换
法拉第效率
聚对苯二甲酸乙二醇酯
离子运输机
化学工程
电化学
光电子学
复合材料
电渗析
电极
有机化学
正渗透
热力学
物理化学
生物化学
反渗透
工程类
物理
化学
作者
Shan Zhou,Menglin Liu,Ruyao Zhang,Yu Gao,Hailin Cong,Bing Yu
标识
DOI:10.1021/acsami.5c04061
摘要
Nanochannel membranes are currently being employed for selective ion transport and salinity gradient energy capture. However, the poor functionality of nanochannel membranes and the unfavorable influence of multivalent cations result in low energy conversion efficiency, limiting the energy conversion performance of nanochannel membranes. Herein, multicomponent nacre-like heterogeneous nanochannels composed of carboxymethyl chitosan (CMC)-intercalated composite two-dimensional (2D) GO, C3N4 nanosheets, and polyethylene terephthalate (PET) channels are developed using an interfacial assembly strategy. Benefiting from the asymmetric structure, the heterogeneous membrane achieves enhanced ion diffusion and unidirectional ion transport behaviors. Subsequently, a high power density of 8.46 W/m2 is achieved in artificial seawater and river water by the heterogeneous membrane. Notably, the introduction of CMC into 2D lamellar channels endows the heterogeneous membrane with outstanding ion sieving performance, thereby mitigating the unfavorable influence of divalent cations on energy conversion, reducing it from 32.08% to 19.85%. Furthermore, the heterogeneous membrane exhibits sensitive and stable light-responsive ion transport behavior, profiting from the light sensitivity of GO and C3N4 nanosheets, and an improvement of 11.29% in energy conversion performance can be accomplished with light irradiation. This work proposes an idea to design multifunctional nanochannel membranes to achieve highly efficient salinity gradient energy conversion.
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