The ongoing search for sustainable and renewable energy solutions to combat energy
shortages and mitigate environmental pollution remains an urgent priority. It catalyzes the …

Electrocatalytic water splitting is considered as the finest and the fastest way for the
production pure hydrogen with no emission of undesired by-products. The efficiency of this …

The exploration of new heterojunction materials is of great significance in reducing the cost
of existing noble metal catalysts and thus realizing the large-scale application of …

Alkaline water electrolysis (AWE) at a low temperature (< 100 C) is one of the most
promising sustainable technologies for green hydrogen production. 1 The AWE process is …

A significant challenge faced by the electrical energy storage (ES) industry in the 21st
century is the creation of ultrahigh performance energy systems that employ safer, more …

The pursuit of efficient and durable catalysts utilizing non-noble metals is critical for
sustainable energy conversion through electrochemical water splitting. Herein, we present a …

Electrocatalysts that perform well at high current densities play a key role in the industrial
implementation of electrochemical water splitting. Recently, bimetallic metal–organic …

Electrocatalytic water decomposition couple with renewable energy is considered as a
green and sustainable method for hydrogen production. However, the development of non …

Noble-metal nanomaterials such as Pt, Ru, and Ir are commonly used as electrocatalysts for
the hydrogen evolution reaction (HER) via efficient water splitting, but the degradation in …

Sustainable energy development can no longer be met by fossil fuels alone. Hence,
electrochemical water splitting containing oxygen and hydrogen evolution reactions is …