Researchers Develop Turing Membrane to Improve Performance of Zinc-based Batteries
Zinc-based batteries are promising options for energy storage devices owing to their low cost and high energy density. However, they may encounter serious dendrite issues, especially at high areal capacities and current densities.
Recently, a research team led by Prof. LI Xianfeng from the Dalian Institute of Chemical Physics (DICP) of the Chinese Academy of Sciences developed novel membranes for zinc-based batteries, achieving uniform zinc deposition with high areal capacity and current density.
This work was published in Journal of the American Chemical Society on July 27.
Dendrite-free zinc-based battery with high areal capacity developed via the region-induced deposition effect of turing membrane (Image by WU Jine)
"We proposed a novel membrane featuring ordered undulating stripes called Turing Patterns, which can effectively suppress zinc dendrites and improve ion conductivity," said Prof. LI.
The crests and troughs in the proposed membrane could effectively adjust the Zn(OH)42- distribution and provide more zinc deposition space. The coordinated Cu ions during membrane formation could interact with Zn(OH)42-, further smoothing zinc deposition.
The researchers found that even at a high current density of 80 mA cm-2, the Turing membrane enabled an alkaline zinc-iron flow battery (AZIFB) to work stably with an ultrahigh areal capacity of 160 mAh cm-2 for approximately 110 cycles, showing an energy efficiency of 90.10%. This is by far the highest value ever reported among zinc-based batteries with such a high current density.
This work provides a new idea for developing high stability zinc-based batteries.
The above work was supported by the Natural Science Foundation of China, CAS Strategic Leading Science & Technology Program (A), and CAS Engineering Laboratory for Electrochemical Energy Storage. (Text by WU Jine)