材料科学
集电器
水溶液
电流(流体)
钝化
焦耳加热
覆盖层
电池(电)
纳米技术
过热(电)
化学工程
工作(物理)
降级(电信)
直流电
工艺工程
氧化剂
光电子学
钛
单层
阴极
工程物理
电加热
水介质
烧结
碳化
作者
Zixiang Meng,Yuhan Zou,Jiashu Chen,Yongbiao Mu,Yan Li,Yuyuan WANG,Qian Liu,Yuyang Yi,Lin Zeng,Guangping Zheng,Shixue Dou,Jingyu Sun
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-03-23
卷期号:20 (13): 10745-10754
被引量:3
标识
DOI:10.1021/acsnano.6c02382
摘要
Al current collectors are widely adopted in nonaqueous batteries because of their low cost, high conductivity, and low density, yet their deployment in aqueous congeners (i.e., Zn-ion batteries) is largely precluded by concurrent issues of surface passivation and electrolyte-driven corrosion. Here, an on-site N-doped carbon-skinned Al current collector (NC@Al) is developed to resolve this longstanding dilemma. Enabled by an ultrafast Joule heating process, elevated temperature carbonization could be completed in seconds without thermally deforming the Al substrate, which renders a dense and continuous double-sided NC overlayer, affording favorable interfacial adhesion. Combined theoretical calculations and experimental diagnostics verify the NC overlayer simultaneously helps suppress the Al passivation–corrosion issue and promote uniform Zn deposition. As a result, symmetric cells based on NC@Al exhibit durable cycling beyond 3500 h at 0.5 mA cm –2 /0.25 mAh cm –2 . When paired with an iodine cathode, our constructed pouch cells with an active material loading of 25 mg cm –2 sustain stable operation for 1000 cycles under a stringent N/P ratio of 1.77. Technoeconomic analysis further highlights the energy-efficiency advantage of our route in practical manufacturing. This work establishes a strategy for employing commercially available Al current collector materials toward aqueous batteries.
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