Exploration of High-Entropy Layered Oxides with Ultrahigh Rate Performance for Sodium-Ion Batteries
Yizhong Chi, Hongkun Tan, Chao Xu, Tianxing Kang, Wei Yang, Hanbo Zou, Shengzhou Chen
Abstract
High Resolution Image Download MS PowerPoint Slide O3-type layered oxides that are of the type of O3 serve as attractive cathode materials for sodium-ion batteries due to their facile production and elevated sodium content. Nonetheless, their practical application is impeded by intricate phase transitions and inadequate air stability. This paper presents a sodium alginate sol–gel approach that utilizes sodium alginate as both a sodium supply and a chelating agent. This method creates a 3D mesh structure through the binding of transition metal salts, facilitating the synthesis of O3-type high-entropy layered oxides. The high-entropy design improves the reversibility of the O3–P3 phase transition, inhibits Na + /H + exchange to decrease air reactivity, and stabilizes the material’s structure, thus minimizing electrochemical deterioration during cycling. DFT calculations demonstrate that the increased Li elements in the high-entropy oxides Na 0.9 Ca 0.05 Fe 0.2 Mn 0.2 Ni 0.2 Ti 0.2 Li x Co 0.2– x O 2 increase the local bonding strengths of TM–O near the Li doping sites and improve the structural stability. The optimized cathode preserves 71% capacity after 200 cycles at 10 C (starting capacity: 117 mAh g –1 ) and sustains 115 mAh g –1 for 100 cycles at 1 C (85.2% retention) after 10 days of exposure to air with 40–50% relative humidity. This study promotes a high-entropy approach for the development of high-performance, air-stable O3-type cathodes for sodium-ion batteries.