<p>Micro-batteries are promising candidates for powering various intelligent integrated applications. However, they typically rely on a single-cell reaction during charging and discharging cycles, limiting improvements in capacity and energy density. Here, we show an in situ conductivity enhancement-assisted double-cell reaction strategy to design high-performance Zn | |Bi<sub>2</sub>O<sub>3</sub>@Ag<sub>2</sub>O micro-batteries that integrate two sequential electrochemical reactions within a single microdevice. Unlike simply combining Zn | |Ag<sub>2</sub>O and Zn | |Bi<sub>2</sub>O<sub>3</sub> micro-batteries, this strategy leverages the in situ conductivity enhancement effect from the Ag<sub>2</sub>O conversion reaction in the first step to significantly boost the discharge capacity (an almost order-of-magnitude improvement compared to Zn | |Bi<sub>2</sub>O<sub>3</sub> micro-batteries alone) of the second conversion reaction, resulting in a total capacity 2.1 times the combined discharge capacities of the two individual micro-batteries. Consequently, the constructed microdevice achieves a high energy density of about 19000 μWh cm<sup>-2</sup> and the microdevice also exhibits a micro-supercapacitor-level or higher power density (above 23000 μW cm<sup>-2</sup>). This work challenges conventional micro-battery configurations and offers a strategy for constructing high-performance micro-power sources for intelligent integrated electronics.</p>

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Dual reaction strategy for in-situ conductivity enhancement to enable high-performing aqueous zinc-based micro-batteries

  • Xinyi Xiu,
  • Li Song,
  • Meng Li,
  • Xiangyang Li,
  • Zhonggui Quan,
  • Xuting Jin,
  • Liangti Qu,
  • Zhen Zhou

摘要

Micro-batteries are promising candidates for powering various intelligent integrated applications. However, they typically rely on a single-cell reaction during charging and discharging cycles, limiting improvements in capacity and energy density. Here, we show an in situ conductivity enhancement-assisted double-cell reaction strategy to design high-performance Zn | |Bi2O3@Ag2O micro-batteries that integrate two sequential electrochemical reactions within a single microdevice. Unlike simply combining Zn | |Ag2O and Zn | |Bi2O3 micro-batteries, this strategy leverages the in situ conductivity enhancement effect from the Ag2O conversion reaction in the first step to significantly boost the discharge capacity (an almost order-of-magnitude improvement compared to Zn | |Bi2O3 micro-batteries alone) of the second conversion reaction, resulting in a total capacity 2.1 times the combined discharge capacities of the two individual micro-batteries. Consequently, the constructed microdevice achieves a high energy density of about 19000 μWh cm-2 and the microdevice also exhibits a micro-supercapacitor-level or higher power density (above 23000 μW cm-2). This work challenges conventional micro-battery configurations and offers a strategy for constructing high-performance micro-power sources for intelligent integrated electronics.