The method allows researchers to ‘harvest’ hydrogen molecules from water while also avoiding many of the limits in current hydrogen production methods. It offers a new avenue of exploration for producing green hydrogen as a sustainable energy source.
Hydrogen as a green energy fuel has long been the focus of countless scientists and industries. Researchers have been on the hunt for decades to find the most economical method to produce green hydrogen reliably to power the energy, transport, and manufacturing and agriculture industries, transforming production across multiple sectors of the global economy.
“We now have a way of extracting sustainable hydrogen, using seawater, which is easily accessible while relying solely on light for green hydrogen production,” said lead author and PhD candidate Luis Campos.
Senior researcher Professor Kourosh Kalantar-Zadeh, from the School of Chemical and Biomolecular Engineering, says the study is a stunning showcase of how the natural chemistry of liquid metals can create hydrogen. His team produced hydrogen with a maximum efficiency of 12.9%, the team is currently working to improve the efficiency for commercialisation.
“For the first proof-of-concept, we consider the efficiency of this technology to be highly competitive. For instance, silicon based solar cells started with six percent in the 1950s and did not pass 10% until the 1990s.”
“Hydrogen offers a clean energy solution for a sustainable future and could play a pivotal role in Australia’s international advantage in a hydrogen economy,” says project co-lead Dr. Francois Allioux.
At the technology’s heart is gallium, a metal with a low melting point, meaning it needs less energy to transition from a solid into a liquid. Professor Kalantar-Zadeh’s team has been pushing the chemical and technical boundaries of liquid metals to create new materials for years. Gallium particles’ ability to absorb light caught their attention.
The result of this finding was a technology using a circular chemical process: particles of gallium are suspended in either seawater or freshwater and activated under sunlight or artificial light. The gallium reacts with the water to become gallium oxyhydroxide and releases hydrogen.
“After we extract hydrogen, the gallium oxyhydroxide can also be reduced back into gallium and reused for future hydrogen production – which we term a circular process,” says Professor Kalantar-Zadeh.
Gallium in liquid state is a fascinating element. At room temperature it looks like solid metal, but when heated to body temperature it transforms into liquid metallic puddles.
Campos said the surface of liquid gallium is very chemically ‘non-sticky,’ and most materials will not attach to it under normal conditions. But when exposed to light in water, liquid gallium reacts at its surface, gradually oxidizing and corroding. This reaction creates clean hydrogen and gallium oxyhydroxide on its surface.
“Gallium has not been explored before as a way to produce hydrogen at high rates when in contact with water – such a simple observation that was ignored previously,” says Professor Kalantar-Zadeh.
The University of Sydney led research was published in Nature Communications.
