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 …

The rapid development of modern consumer electronics is placing higher demands on the
lithium cobalt oxide (LiCoO2; LCO) cathode that powers them. Increasing operating voltage …

Understanding reactions at the electrode/electrolyte interface (EEI) is essential to
develo** strategies to enhance cycle life and safety of lithium batteries. Despite research …

High‐voltage LiCoO2 delivers a high capacity but sharp fading is a critical issue, and the
capacity decay mechanism is also poorly understood. Herein, we clarify that the escape of …

The electrode–electrolyte interface has been a critical concern since the birth of lithium (Li)-
based batteries (lithium or Li+-ion batteries) that are operated with liquid electrolytes and in …

The working mechanism of LiCoO2 beyond 4.6 V presents complicated issues:(1) the
ambiguous multistructural evolutions,(2) the vague O-related anionic redox reactions (ARR) …

By breaking through the energy density limits step-by-step, the use of lithium cobalt oxide-
based Li-ion batteries (LCO-based LIBs) has led to the unprecedented success of consumer …

The development of high‐voltage LiCoO2 is essential for achieving lithium‐ion batteries with
high volumetric energy density, however, it faces a great deal of challenges owing to the …

This overview addresses the atomistic aspects of degradation of layered LiMO 2 (M= Ni, Co,
Mn) oxide Li-ion battery cathode materials, aiming to shed light on the fundamental …

Identifying and understanding relationships between the electronic and atomic structure of
surfaces and their catalytic activity is an essential step towards the rational design of …