电解质
锂(药物)
聚合物
化学工程
惰性
电化学
材料科学
纳米技术
图层(电子)
沉积(地质)
化学气相沉积
多硫化物
分子
衍生化
电导率
离子电导率
金属
电极
溶剂
无机化学
原子层沉积
离子
纳米材料
电池(电)
离子键合
共价键
化学稳定性
纳米颗粒
保形涂层
动力学
水溶液
纳米尺度
降水
作者
Shuo Jin,Pengyu Chen,Shifeng Hong,Haonian Shu,Xiaosi Gao,Ziang Gao,Samuel Baffour,Mingjia Fang,Yong Lak Joo,Rong Yang,Lynden A. Archer
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2025-10-08
卷期号:11 (41): eady4460-eady4460
被引量:4
标识
DOI:10.1126/sciadv.ady4460
摘要
Scalable synthesis of electrochemically inert nanofilms with precise spatial and compositional control enables rational design of solid-electrolyte interphases (SEIs) in rechargeable batteries. Ion and molecule transport through SEIs largely determines the cycling stability of high-energy rechargeable metal and metal-ion batteries, where electroreduction during charging often occurs beyond electrolyte stability limits. We report nanometer-thick gradient zwitterionic polymer (G-ZWP) interphases, synthesized via a scalable solvent-free method, to regulate transport and electroreduction kinetics at Li-metal anodes, achieving stable cycling. The synthesis combines initiated chemical vapor deposition and diffusion-limited vapor derivatization to form a zwitterionic top layer with high ionic conductivity and an inner covalently cross-linked layer blocking solvent access while remaining stable at reducing potentials. Cu substrates with G-ZWP interphases show >2000-hour cycling at 1 milliampere per square centimeter [6 milliampere hours per square centimeter (mA·hour/cm 2 )]. The interphases also enable long-term cycling of Li batteries (N/P = 0 to 2.5) and Li–dry-air batteries (10 mA·hour/cm 2 ) and stabilize Na/Zn electrodeposition.
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