High-entropy materials (HEMs) hold promise for a variety of applications because their
properties can be readily tailored by selecting specific elements and altering stoichiometry …

Since the electrochemical de/intercalation behavior is first detected in 1980, layered oxides
have become the most promising cathode material for alkali metal‐ion batteries (Li+/Na+/K+; …

Abstract High‐entropy oxides (HEOs), which incorporate multiple‐principal cations into
single‐phase crystals and interact with diverse metal ions, extend the border for available …

Develo** highly efficient and durable electrocatalysts toward oxygen evolution reaction
(OER) is an urgent demand to produce clean hydrogen energy. In this study, a series of …

High-entropy materials (HEMs) have garnered extensive attention owing to their diverse and
captivating physicochemical properties. Yet, fine-tuning morphological properties of HEMs …

For Li–air batteries (LABs), the performance enhancement is significantly restricted by the
lack of highly efficient cathode catalysts. It is difficult to achieve multiphase catalysis to …

The low energy density, safety concerns, and high cost associated with conventional lithium‐
ion batteries pose challenges in meeting the growing demands of emerging applications …

The high-entropy silicon anodes are attractive for enhancing electronic and Li-ionic
conductivity while mitigating volume effects for advanced Li-ion batteries (LIBs), but are …

High entropy materials (HEMs) have attracted significant attention in catalysis due to their
adjustable constituents, unique electronic configurations, abundant active sites as well as …

The strong electrostatic interaction between high‐charge‐density zinc ions (112 C mm− 3)
and the fixed crystallinity of traditional oxide cathodes with delayed charge compensation …