EN

X. Wang, H.J. Huang, F. Zhou, P. Das, P.C. Wen, S.H. Zheng, P.F. Lu, Yan Yu* and Z.-S. Wu*  
Nano Energy, 2021, 8, 105688.
DOI: 10.1016/j.nanoen.2020.105688 [PDF]

发布时间:2020-12-10    栏目名称:2021

X. Wang, H.J. Huang, F. Zhou, P. Das, P.C. Wen, S.H. Zheng, P.F. Lu, Yan Yu* and Z.-S. Wu*

Nano Energy, 2021, 8, 105688.

DOI: 10.1016/j.nanoen.2020.105688 [PDF]

Aqueous sodium ion micro-batteries (ANIMBs) hold great promise in smart wearable microelectronics due to the abundant reserves, low cost and high safety of sodium. However, their applications are substantially hindered by the narrow electrochemical stability window of aqueous electrolytes within a limited temperature range. Herein, we report a prototype of high-voltage planar ANIMBs based on symmetric interdigital microelectrodes working in water-in-salt (WiS) electrolyte (17 M NaClO4) and displaying exceptional performance at low temperature. This work features nanoflower Na3V2(PO4)3(NVP)-based electrodes with perfectly matched voltage range as both anode and cathode in the WiS electrolyte operating in a widened electrochemical stability window (2.7 Vvs.Na+/Na) under ultralow freezing point of −50 ºC. The resulting ANIMBs with interdigital in-plane geometry deliver remarkable volumetric capacity of 45 mAh/cm3and energy density of 77 mWh/cm3, which are superior to most reported sodium-based micropower sources. Notably, the NVP||NaClO4||NVP micro-batteries exhibit a high coulombic efficiency of > 99% at room temperature down to −40 ºC. Furthermore, the NVP||NaClO4||NVP ANIMBs present admirable flexibility and modular integration. We believe that our ANIMBs can potentially enjoy wide market adoption ranging from domestic appliances to safe intelligent wearable microelectronics, especially those applications that need to be operated below freezing temperature.

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