Lithium transition metal oxide layers, Li [Ni1− x− yCox (Mn and/or Al) y] O2, are widely used
and mass-produced for current rechargeable battery cathodes. Development of cathode …

Recharging battery‐powered electric vehicles (EVs) in a similar timeframe as those used for
refueling gas‐powered internal combustion vehicles is highly desirable for rapid penetration …

Substantial endeavors are dedicated to advance the electrochemical performance of Ni‐rich
Li [Ni1− x− yCoxMny] O2 (NCM) and Li [Ni1− x− yCoxAly] O2 (NCA) cathode, with a …

The wide-ranging application of lithium-ion batteries (LIBs) is currently restricted by their
slow ion dynamics and low capacity, which hinders the development of innovative electrode …

The development of mixed structures is increasingly becoming an efficient way to improve
the performance of layered oxide cathodes for sodium-ion batteries. Herein, the Na 0.8 Mn …

Defect engineering is demonstrated to be an important factor in enhancing the
electrochemical performance of lithium‐ion batteries by improving structural stability and ion …

High‐voltage cathodes (HVCs) have emerged as a paramount role for the next‐generation
high‐energy‐density lithium‐ion batteries (LIBs). However, the pursuit of HVCs comes with …

Solid‐state lithium batteries (SSLBs) have great development prospects in high‐security
new energy fields, but face major challenges such as poor charge transfer kinetics, high …

Ni-rich cathodes with a radial ordered microstructure have been proved to enhance
materials' structural stability. However, the construction process of radial structures has not …

Given that the oxygen evolution reaction (OER) faces challenges due to its sluggish kinetics,
development of efficient and robust OER catalytic electrodes is critical for reducing the cost …