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http://dx.doi.org/10.3740/MRSK.2022.32.4.216

Stabilization of High Nickel Cathode Materials with Core-Shell Structure via Co-precipitation Method  

Kim, Minjeong (Chungnam National University)
Hong, Soonhyun (Chungnam National University)
Jeon, Heongkwon (Chungnam National University)
Koo, Jahun (Chungnam National University)
Lee, Heesang (Chungnam National University)
Choi, Gyuseok (Gumi Electronic and Information Technology Research Institute)
Kim, Chunjoong (Chungnam National University)
Publication Information
Korean Journal of Materials Research / v.32, no.4, 2022 , pp. 216-222 More about this Journal
Abstract
The capacity of high nickel Li(NixCoyMn1-x-y)O2 (NCM, x ≥ 0.8) cathodes is known to rapidly decline, a serious problem that needs to be solved in a timely manner. It was reported that cathode materials with the {010} plane exposed toward the outside, i.e., a radial structure, can provide facile Li+ diffusion paths and stress buffer during repeated cycles. In addition, cathodes with a core-shell composition gradient are of great interest. For example, a stable surface structure can be achieved using relatively low nickel content on the surface. In this study, precursors of the high-nickel NCM were synthesized by coprecipitation in ambient atmosphere. Then, a transition metal solution for coprecipitation was replaced with a low nickel content and the coprecipitation reaction proceeded for the desired time. The electrochemical analysis of the core-shell cathode showed a capacity retention of 94 % after 100 cycles, compared to the initial discharge capacity of 184.74 mA h/g. The rate capability test also confirmed that the core-shell cathode had enhanced kinetics during charging and discharging at 1 A/g.
Keywords
lithium-ion battery; cathode; high-Ni cathode; core-shell; co-precipitation method;
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