A new design with an alternately stacked electrode configuration helped to enhance the volumetric performance of supercapacitors and attain high energy density without sacrificing power performance.
This research, which introduced the alternately stacked electrode structure into a compact energy storage system for the first time, was conducted by Prof. Han Fangming from the Institute of Solid State physics, Hefei Institutes of Physical Science and Prof. WEI Bingqing from University of Delaware, Newark, U.S..
In this work, the researchers designed an alternately multilayer stacked film electrode structure using Ti3C2Tx (MXene) films as the electrodes, and gel electrolyte as the separator.
This new structure could shorten the transport distance of ions under high mass loadings, and increase the mass loading of active material at device scale, without increasing the mass loadings of each single electrode.
Thus, the supercapacitor with the alternately stacked configuration showed ultrahigh areal capacitance of 10.8 F cm-2, high volumetric energy density of 10.4 mWh cm-3 at 75.0 mW cm-3, and simultaneously maintained high power performance
“It has the highest values in an aqueous gel electrolyte system compared to the literature,” said Prof. Han.
With the trend of miniaturization and portability of electronic devices, it is essential to improve the volumetric energy density of electrochemical energy storage devices. High mass loadings can decrease the inactive component ratio at the device level, thereby leading to increased energy density as well as decreased cost.
Unfortunately, the increase of the mass loadings usually comes at the cost of losses in specific capacitance and power density.
Dou Lin et al. Alternately stacked thin film electrodes for high-performance compact energy storage, Nano Energy (2020). DOI: 10.1016/j.nanoen.2020.105323
Chinese Academy of Sciences
New electrode configuration improves volumetric performance of supercapacitors (2020, September 8)
retrieved 8 September 2020
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