Since the advent of the Li ion batteries (LIBs), the energy density has been tripled, mainly
attributed to the increase of the electrode capacities. Now, the capacity of transition metal …

Layered lithium transition metal oxides derived from LiMO2 (M= Co, Ni, Mn, etc.) have been
widely adopted as the cathodes of Li-ion batteries for portable electronics, electric vehicles …

Oxygen redox cathodes, such as Li1. 2Ni0. 13Co0. 13Mn0. 54O2, deliver higher energy
densities than those based on transition metal redox alone. However, they commonly exhibit …

Abstract Li [Li x Ni y Mn z Co1− x− y− z] O2 (lithium-rich NMCs) are benchmark cathode
materials receiving considerable attention due to the abnormally high capacities resulting …

The oxygen redox reaction in lithium-rich layered oxide battery cathode materials generates
extra capacity at high cell voltages (ie,> 4.5 V). However, the irreversible oxygen release …

Pushing the limit of cutoff potentials allows nickel‐rich layered oxides to provide greater
energy density and specific capacity whereas reducing thermodynamic and kinetic stability …

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 …

Attempts to utilize lithium-ion batteries (LIBs) in large-scale electrochemical energy storage
systems have achieved initial success, and solid-state LIBs using metallic lithium as the …

As the demand for lithium-ion batteries grows exponentially to feed the nascent electric-
vehicle and grid-storage markets, the need for higher energy density and longer cycle life …

High-voltage phase transition constitutes the major barrier to accessing high energy density
in layered cathodes. However, questions remain regarding the origin of phase transition …