In addition to hydrogen production using renewable sources, hydrogen storage plays a key role in the development of hydrogen energy
We underlined different essential aspects for the future development of HEAs as hydrogen storage materials. This review article discusses and describes the perspectives of
Five or more elements must be combined in equal or fairly substantial amounts to form high-entropy alloys (HEAs). A future hydrogen-based energy system will require
Magnesium series hydrogen storage alloys: MgNi 2 is a typical magnesium material, which has great potential for light and high energy hydrogen storage materials.
Hydrogen energy has gained widespread recognition for its environmentally friendly nature, high energy density and abundant resources, making it a promising energy
The selection process minimized reliance on time-consuming experimental methods. Hydrogen is a clean energy carrier and has potential applications in energy storage,
An extensive exploration of the chemical space was conducted to design and identify promising multicomponent cubic alloys with appropriate
Abstract Compositionally complex and high entropy alloys have emerged as promising candidates for hydrogen storage in the transition towards sustainable energy
Solid-state hydrogen storage materials that are optimized for specific use cases could be a crucial facilitator of the hydrogen economy
In the present investigation, the synthesis, structural and microstructural characterisation, and hydrogen storage behaviour of a single-phase body-centered cubic
An extensive exploration of the chemical space was conducted to design and identify promising multicomponent cubic alloys with appropriate enthalpy of reaction for
Abstract Magnesium-based alloys attract significant interest as cost-efficient hydrogen storage materials allowing the combination of high
In this work, we concentrate on Mg alloys for hydrogen storage, and construct the ML regression models to predict two important parameters of hydrogen storage properties,
Abstract An efficient and safe hydrogen storage method is one of the important links for the largescale development of hydrogen in the future. - Because of its low price and simple design,
Development of new materials with high hydrogen storage capacity and reversible hydrogen sorption performances under mild conditions has very high value in both
Abstract High-entropy alloys (HEAs) have gained considerable attention for their exceptional properties, positioning them as promising candidates for the advancement of
Abstract Magnesium-based alloys attract significant interest as cost-efficient hydrogen storage materials allowing the combination of high gravimetric storage capacity of
In this paper, a design method for high-entropy alloys is provided, and a high-entropy alloy that can absorb hydrogen at room temperature is developed, but its hydrogen
1. Introduction Metal hydrides (MHs) are chemical compounds that form when hydrogen reacts with metals or alloys. The formation of these compounds offers an opportunity
Hydrogen storage alloys enable efficient, safe hydrogen use in energy systems, supporting grid storage, transport, and the global clean energy transition.
Within a few years, hydrogen is expected to play a major role as the source of power in vehicles. Several research efforts are being spent in
Recently, a new class of alloys, namely, high-entropy alloys (HEAs), started to be investigated for hydrogen storage as they can form metal
After being activated, TiFe alloys are widely concerned for their high hydrogen storage density due to their large reversible absorption and desorption capacity of hydrogen at
With further exploration of alloy composition and material processing, there are great chances in using hydrogen storage amorphous alloys as energy storage material.
Furthermore, this review introduces popular research directions in BCC-based solid solution hydrogen storage alloys. Specifically, it highlights the growing interest in low/free
Considering the role of hydrogen in global energy sustainability [41], it becomes very essential to report various alloys explored/tested, and their key features as a solid-state
High entropy alloys (HEAs) are distinguished for their unique properties, particularly in hydrogen storage applications. Their diverse compositions offer significant
His research focuses on amorphous and nanocrystalline materials synthesized by mechanochemical synthesis – mostly according to their utility as hydrogen
Among them, alloys have become leading hydrogen-storage materials owing to their favorable cost, safety, operating conditions, particularly their high energy density by volume.
Abstract High entropy alloys (HEAs) are distinguished for their unique properties, particularly in hydrogen storage applications. Their diverse compositions offer significant
In this review, we combed through the definition and criteria of high entropy alloys, and summarized the current research status of body
