The electrocatalytic process of water splitting offers a promising approach to produce
sustainable hydrogen. However, the slow kinetics of the oxygen evolution reaction (OER) …

The splitting of water through electrocatalysis offers a sustainable method for the production
of hydrogen. In alkaline electrolytes, the lack of protons forces water dissociation to occur …

With the deep integration of electrochemical research with energy, environment, catalysis,
and other fields, more and more new electrochemical catalytic reactions have entered our …

High-entropy nanomaterials are regarded as the new research hotspots for their intriguing
“cocktail effect”. Herein, self-supported PtPdMnCoFe high-entropy alloy with nanochain-like …

Rational design and dynamic reconstruction of efficient electrocatalysts have aroused great
interest for the development of water splitting. Herein, coupling of do**, high entropy and …

Abstract High-entropy alloys (HEAs), also known as multi-principal component alloys,
possess a range of attractive properties that cannot be achieved by traditional alloys due to …

The availability of hydrogen energy from water splitting through the electrocatalytic route is
strongly dependent on the efficiency, durability, and cost of the electrocatalysts. Herein, a …

Abstract Two‐dimensional (2D) high‐entropy alloys (HEAs) have emerged as promising
electrocatalysts due to the benefits of polymetallic coordination and robust electrical …

Unraveling the mechanism driven by electronegativity‐dominated electronic configuration is
crucial for develo** high‐entropy alloys as efficient catalyst for hydrogen evolution …

Electrocatalytic hydrogen evolution via water splitting occurs at the electrode surface,
particularly at the solid–liquid interfaces. Establishing boundary electron transfer channels is …