Electrochemical Assessment of Highly Reversible Sno2-Coated Zn Metal Anodes Prepared Via Atomic Layer Deposition for Aqueous Zn-Ion Batteries

Aqueous electrochemical energy storage systems that rely on earth-abundant elements are considered as cost-effective alternatives to current lithium-ion batteries which have dominated the technological landscape. For zinc-based energy storage, dendrite growth is an underlying challenge that needs to be addressed to enact high performance and long-term stability. In the present study, we employ atomic layer deposition to produce a thin tin oxide layer that allows dendrite-free cycling for aqueous zinc-ion batteries. Tin oxide is particularly interesting as it provides two distinct advantages—dendrite-free cycling and mitigation of parasitic hydrogen gas evolution. The presence of the tin oxide layer leads to hydrogen gas suppression and homogeneous zinc plating/stripping, both of which are essential to improve the performance of zinc-ion batteries. When paired in a full-cell configuration with manganese oxide, this anode delivers a high specific capacity of 250 mAh g –1 at an imposed current rate of 30 mA g –1 . Through density functional theory calculations, we elucidate further that the adsorption energy of Zn for bare Zn is higher than that in the presence of a tin oxide layer.

Keywords: Aqueous zinc-ion battery, Zinc metal anode, atomic layer deposition, Tin oxide

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Gong, Sang Hyuk and Lim, Hyo Jin and Lee, Ji Hyeon and Yoo, Yiseul and Yu, Seungho and Lim, Hee-Dae and Jung, Hyun Wook and Ko, Jesse S. and Kim, In Soo and Kim, Hyung-Seok, Electrochemical Assessment of Highly Reversible Sno2-Coated Zn Metal Anodes Prepared Via Atomic Layer Deposition for Aqueous Zn-Ion Batteries. Available at SSRN: https://ssrn.com/abstract=4216079 or http://dx.doi.org/10.2139/ssrn.4216079