Lithium‐rich manganese‐based layered oxides (LMLOs) are considered to be one type of
the most promising materials for next‐generation cathodes of lithium batteries due to their …

Enhancing the charge cut‐off voltage of LiCoO2 at 4.6 V can improve the battery density,
however, structural instability is a critical challenge (eg, electrolyte decomposition, Co …

Despite their ultrahigh specific capacity, lithium‐rich layered oxide cathodes are still plagued
by challenges such as poor cycle stability and notorious voltage decay, which are primarily …

Earth-abundant cathode materials are urgently needed to enable scaling of the Li-ion
industry to multiply terawatt hours of annual production, necessitating reconsideration of …

Li‐rich layered oxides based on the anionic redox chemistry provide the highest practical
capacity among all transition metal (TM) oxide cathodes but still struggle with poor cycling …

The rapid expansion of renewable energies asks for great progress of energy-storage
technologies for sustainable energy supplies, which raises the compelling demand of high …

Manganese-based materials have tremendous potential to become the next-generation
lithium-ion cathode as they are Earth abundant, low cost and stable. Here we show how the …

Li-rich oxides (LROs) working on a synergy of cation and anion redox can deliver greater
energy density than that of commercial cathode materials. However, the lattice strain and …

Recently, strategies of optimizing cathode/electrolyte interphase (CEI) have been applied to
enhance the durability of LiCoO2 (LCO) at high voltages (≥ 4.55 V vs Li/Li+) and high …

Diluents have been extensively employed to overcome the disadvantages of high viscosity
and sluggish kinetics of high‐concentration electrolytes, but generally do not change the …