Journal
ACS ENERGY LETTERS
Volume 6, Issue 2, Pages 404-412Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acsenergylett.0c02343
Keywords
-
Categories
Funding
- Georgia Institute of Technology
- National Science Foundation [ECCS-1542174]
Ask authors/readers for more resources
Rechargeable aqueous zinc anodes are attracting attention for their safety, low cost, and high theoretical volumetric capacity. Zinc anodes in aqueous electrolytes often suffer from dendritic metal deposition, with the regulation of Zn using Zn-alloying metals as a reported solution. By introducing Ag on Zn anodes, uniform Zn deposition was achieved, leading to improved cycling performance. This alloy-seeding design principle could potentially enhance the rechargeability of other metal anodes.
Rechargeable aqueous zinc anodes have gained tremendous attention because of their merits of intrinsic safety, low cost, and high theoretical volumetric capacity (5854 mAh cm(-3) for Zn metal). In aqueous electrolytes, zinc anodes suffer from severe dendritic metal deposition. The regulation of Zn by inducing Zn-alloying metals has been reported. However, the underlying mechanisms have remained elusive. Here, for the first time, we did a comprehensive analysis to elucidate the mechanisms for the seeded and nondendritic growth of Zn on alloy anodes. We achieved uniform Zn deposition by introducing a Zn-alloying and soluble metal, Ag, on Zn anodes. Due to a shift of thermodynamic potential and the spatial confinement, the Ag-modified Zn anode exhibited improved overall cycling performance compared with previous deep-cycle Zn anodes. Furthermore, the seeded Zn deposition was visualized in operando for the first time using an optical microscope. The alloy-seeding design principle here can potentially be applied to improve the rechargeability of other metal anodes.
Authors
I am an author on this paper
Click your name to claim this paper and add it to your profile.
Reviews
Recommended
No Data Available