制氢
材料科学
氢
渗透力
电解
反向电渗析
可再生能源
功率密度
能量收集
化学工程
分解水
电解水
高压电解
发电
氢燃料
膜
纳米技术
堆栈(抽象数据类型)
电极
储能
堆积
电力转天然气
缩放比例
电压
微生物电解槽
能量转换
生物量(生态学)
工艺工程
聚合物电解质膜电解
缓压渗透
电流密度
作者
Jianwei He,Xuejiang Li,Wenna Li,Jin Zhai,Fan Xia
标识
DOI:10.1002/adma.202514316
摘要
Abstract Harnessing renewable energy for green hydrogen production is critical for decarbonization. An ideal, sustainable route involves self‐powered hydrogen production without additional energy input. Here, the osmotic energy between seawater and river water is used to continuously generate electricity to directly produce hydrogen. Efficient hydrogen production is successfully achieved by connecting the osmotic energy device composed of the polyamide acid PAA37 ion selective membrane and the water electrolysis device in series. The PAA37 membrane, featuring engineered sub‐nanometer channels, exhibits an ultra‐high cation transference number (t+ = 0.96). Targeting the critical challenge of scaling up osmotic power generation, the HLZ equation is introduced. It theoretically establishes that the decline in power density under large‐area conditions is primarily attributed to the electrode impedance within the low‐concentration zone. This finding offers a theoretical foundation for guiding the optimization of large‐scale device designs. Consequently, the PAA37 membrane achieves a power density of 6.0 W m −2 over a macroscopic area of 3.14 mm 2 under a 50‐fold KCl. Furthermore, by stacking 110 RED units in series, a remarkable output voltage of 24.3 V is generated. By arranging this stack in series and parallel, the system successfully powers an electrolyzer for direct hydrogen production.
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