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Ultralow-resistance electrochemical capacitor for integrable line filtering.

Yajie HuMingmao WuFengyao ChiGuobin LaiPuying LiWenya HeBing LuChuanxin WengJinguo LinFengen ChenHuhu ChengFeng LiuLan JiangLiang-Ti Qu
Published in: Nature (2023)
Electrochemical capacitors are expected to replace conventional electrolytic capacitors in line filtering for integrated circuits and portable electronics 1-8 . However, practical implementation of electrochemical capacitors into line-filtering circuits has not yet been achieved owing to the difficulty in synergistic accomplishment of fast responses, high specific capacitance, miniaturization and circuit-compatible integration 1,4,5,9-12 . Here we propose an electric-field enhancement strategy to promote frequency characteristics and capacitance simultaneously. By downscaling the channel width with femtosecond-laser scribing, a miniaturized narrow-channel in-plane electrochemical capacitor shows drastically reduced ionic resistances within both the electrode material and the electrolyte, leading to an ultralow series resistance of 39 mΩ cm 2 at 120 Hz. As a consequence, an ultrahigh areal capacitance of up to 5.2 mF cm -2 is achieved with a phase angle of -80° at 120 Hz, twice as large as one of the highest reported previously 4,13,14 , and little degradation is observed over 1,000,000 cycles. Scalable integration of this electrochemical capacitor into microcircuitry shows a high integration density of 80 cells cm -2 and on-demand customization of capacitance and voltage. In light of excellent filtering performances and circuit compatibility, this work presents an important step of line-filtering electrochemical capacitors towards practical applications in integrated circuits and flexible electronics.
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