Nickel‐rich layered transition‐metal oxides with high‐capacity and high‐power capabilities
are established as the principal cathode candidates for next‐generation lithium‐ion …

Solid-state fast ionic conductors are of great interest due to their application potential
enabling the development of safer high-performance energy and conversion systems …

Recycling of waste electronics to recover raw materials is beneficial for the environment,
particularly for electronic devices containing expensive metals such as lithium-ion batteries …

Designing new cathodes with high capacity and moderate potential is the key to breaking
the energy density ceiling imposed by current intercalation chemistry on rechargeable …

The critical challenges for fluoride conversion cathodes lie in the absence of built-in Li
source, poor capacity retention, and rate performance. For lithiated fluorides, the reason to …

Pairing Li-free transition-metal-based cathodes (MX) with Li-metal anodes is an emerging
trend to overcome the energy-density limitation of current rechargeable Li-ion technology …

Interfacial materials design is critical in the development of all-solid-state lithium batteries.
We must develop an electrode–electrolyte interface with low resistance and effectively utilize …

Developing cathode materials with high specific capability and excellent electrochemical
performance is crucial for the advancement of aluminum-ion batteries, which leverage the …

Most of sodium-layered oxide cathodes are unstable under moisture conditions. As a unique
water-stable cathode, Na2/3Ni1/3Mn2/3O2 (NNM) usually becomes vulnerable to water …

The voltage is a key parameter for the performance of Li-ion cells. An increased average
voltage results in a higher energy-and power density. Theoretically, the potential of Li …