Insights into the Facet and Morphological Domination on the Electrochemical Performance of Layered NaNi_1/3Fe_1/3Mn_1/3O₂ for Sodium-Ion Batteries

Abstract: While multitransition-metal layered oxides in the form of micrometer-sized single crystals and polycrystalline aggregates show great promise as affordable cathodes for sodiumion batteries, the relationship between a typical preferential facet as well as morphological domination and electrochemical performance in both forms remains unclear. In this regard, herein, two models of layered O3-type NaNi 1/3 Fe 1/3 Mn 1/3 O 2 (NFM) materials with single-crystalline and polycrystalline characteristics were prepared. B… Show more

“…This indicates that Y 3+ substitution can effectively improve the rate capability of NFM, which is due to the expanded d -spacing between the TM slabs. In addition, the rate capability at 5C of NFMY1 in our work and the modified NFM in published papers was compared, 4,37,49,57,59–67 and the results are shown in Fig. 5.…”

A high-rate and air-stable cathode material for sodium-ion batteries: yttrium-substituted O3-type Ni/Fe/Mn-based layered oxides

“…This indicates that Y 3+ substitution can effectively improve the rate capability of NFM, which is due to the expanded d -spacing between the TM slabs. In addition, the rate capability at 5C of NFMY1 in our work and the modified NFM in published papers was compared, 4,37,49,57,59–67 and the results are shown in Fig. 5.…”

A high-rate and air-stable cathode material for sodium-ion batteries: yttrium-substituted O3-type Ni/Fe/Mn-based layered oxides

High-entropy configuration of O3-type layered transition-metal oxide cathode with high-voltage stability for sodium-ion batteries