Intercalation chemistry has dominated electrochemical energy storage for decades, and
storage capacity worldwide has now reached the terawatt-hour level. State-of-the-art …

Abstract Layered Li [Ni x Co y M z] O 2 (M= Mn or Al, so-called NCM/NCA) ternary cathode
materials have attracted a lot of intensive research efforts for high-performance lithium-ion …

Lithium-rich layered oxides (LLOs), also known as Li 1+ x M 1− x O 2 or x Li 2 MnO 3-(1–x)
LiMO 2 (M= Ni, Co, Mn), have been regarded as some of the highest capacity lithium …

Rechargeable Li-ion battery has been regarded as the most effective electrochemical
energy storage device because of its high energy density and power density of 3 and 6 …

Cathode degradation is a key factor that limits the lifetime of Li-ion batteries. To identify
functional coatings that can suppress this degradation, we present a high-throughput density …

The need for high-energy, low-cost batteries is projected to grow dramatically in the next
decade due to electrification of the transportation market. Such demands are straining Li-ion …

Electrochemistry-driven techniques for advanced energy storage/conversion and
environmental protection play a crucial role in achieving sustainable development goals. As …

Lithium-rich layered oxide is recognized as a prospective cathode material for next-
generation batteries as it has a high theoretical specific capacity. They, however, suffer from …

A green process route to recycle LiFePO4/C electrode materials is proposed in this work.
First, a robust strategy to synthesize LiFePO4/C cathode materials from a precursor of a …

As promising cathode materials in Li-ion batteries, Li-rich layered oxides still suffer from
unsatisfactory rate capability and cyclic stability during cycling. Herein, vanadium doped Li …