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Printable Zinc-Ion Hybrid Micro-Capacitors for Flexible Self-Powered Integrated Units
Nano-Micro Letters ( IF 31.6 ) Pub Date : 2020-11-05 , DOI: 10.1007/s40820-020-00546-7 Juan Zeng 1 , Liubing Dong 2 , Lulu Sun 3 , Wen Wang 3 , Yinhua Zhou 3 , Lu Wei 1 , Xin Guo 1
中文翻译:
用于柔性自供电集成单元的可印刷锌离子混合微电容器
更新日期:2020-11-05
Nano-Micro Letters ( IF 31.6 ) Pub Date : 2020-11-05 , DOI: 10.1007/s40820-020-00546-7 Juan Zeng 1 , Liubing Dong 2 , Lulu Sun 3 , Wen Wang 3 , Yinhua Zhou 3 , Lu Wei 1 , Xin Guo 1
Affiliation
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This work is a new guide for the design of on-chip energy integrated systems toward the goal of developing highly safe, economic, and long-life smart wearable electronics.
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The biomass kelp-carbon based on unique 3D micro-/nanostructure combined with multivalent ion storage contributes to high capacity of the Zn-ion hybrid capacitor.
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The flexible solar-charging self-powered system with printed Zn-ion hybrid micro-capacitor as energy storage module exhibits fast photoelectric conversion/storage rate, good mechanical robustness, and cyclic stability.
中文翻译:
用于柔性自供电集成单元的可印刷锌离子混合微电容器
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这项工作为片上能源集成系统的设计提供了新的指导,以实现开发高度安全、经济和长寿命的智能可穿戴电子产品的目标。
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基于独特的 3D 微/纳米结构的生物质海带碳与多价离子存储相结合,有助于实现锌离子混合电容器的高容量。
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以印刷锌离子混合微电容器为储能模块的柔性太阳能充电自供电系统具有快速的光电转换/存储速率、良好的机械鲁棒性和循环稳定性。