4.8 Article

High Cycling Rate-Induced Irreversible TMO6 Slabs Glide in Co-Free High-Ni Layered Cathode Materials

Journal

ADVANCED FUNCTIONAL MATERIALS
Volume -, Issue -, Pages -

Publisher

WILEY-V C H VERLAG GMBH
DOI: 10.1002/adfm.202301650

Keywords

cobalt free cathodes; high nickel; layered oxide cathodes; lithium-ion batteries; structural evolution

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Co-free high-Ni layered transition metal oxide is a promising cathode material for Li-ion batteries, but its rate performance and capacity decay during high-rate cycling are problematic. This study reveals the atomic scale structural changes of Co-free high-Ni layered cathode under different cycling rates using advanced TEM characterization. The structural evolutions after high-rate cycling are different from those after low-rate cycling, showing severe lattice distortion and structural dislocations. These findings deepen the understanding of the rate-dependent structural degradation mechanism and have implications for improving cathode materials for high-rate applications.
Co-free high-Ni layered transition metal oxide is a promising cost-effective cathode material for high-energy Li-ion batteries, but it suffers from undesirable rate performance and rapid capacity decay upon high-rate cycling. The underlying structural changes under fast electrochemical processes remain unclear to date. In this study, atomic scale structural evolutions of Co-free high-Ni layered cathode at different cycling rates are revealed by advanced TEM characterization. It is found that the phase transition after high-rate cycling is much different from that after low-rate cycling. The low-rate cycled sample shows a typical layer-to-rock salt transition. However, O1-type stacking faults are uncovered in the high-rate cycled sample owing to irreversible TMO6 slabs glide, which induces severe lattice distortion and structural dislocations. These findings deepen the understanding of the rate-dependent structural degradation mechanism of Co-free high-Ni layered cathodes, and have significant implications for improving current materials to withstand high-rate applications.

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