Hydrogen is expected to play a central role in future clean energy systems, but storing it efficiently and safely remains one of the biggest challenges to its widespread adoption. Solid-state hydrogen ...

As an energy carrier, hydrogen holds the prominent advantages of high gravimetric energy density, high abundance, and zero emission, yet its effective storage and transportation remain a bottleneck ...

DIVE systematically organizes the information it pulls from existing literature regarding solid-state hydrogen storage materials. Its accuracy and coverage of data extraction was 10–15% better than ...

Magnesium hydride has long been touted for its potential to store large amounts of hydrogen, something essential if hydrogen is to play a role in powering a sustainable future. Yet, sluggish ...

Developing new materials can involve a dizzying amount of trial and error for different configurations and elements. Artificial intelligence (AI) has seen a surge of popularity in energy materials ...

Despite years of research, materials like metal hydrides and coordination hydrides face limitations such as low storage density, inappropriate thermodynamic temperature, slow kinetic rates, and poor ...

A nanoporous material that holds hydrogen at twice the density of cryogenic liquid H2 could address the challenges of large-scale liquid and gas storage that have held this clean fuel back. Hydrogen ...

Hydrogen storage technologies are an essential element of the transition to alternative fuels and net zero carbon emissions. These technologies require the design of suitable advanced materials which ...

A research team has identified materials capable of catalyzing the conversion of ortho-hydrogen to para-hydrogen. These catalysts should be essential to the spread of mass-transportation/storage of ...