A study developed jointly by Istituto Italiano di Tecnologia (IIT) and the spin-off BeDimensional has identified a solution based on ruthenium particles and a solar-powered electrolytic system.

Small ruthenium particles and a solar-powered system for water electrolysis can produce green hydrogen more efficiently and cheaply.

The technology, developed in the context of the Joint-lab’s activities and recently published in two high-impact factor journals (Nature Communications and the Journal of the American Chemical Society) is based on a new family of electrocatalysts that could reduce the costs of green hydrogen production on an industrial scale.

IIT and BeDimensional’s researchers used nanoparticles of ruthenium, a noble metal that is similar to platinum in its chemical behavior but far cheaper, to serve as the active phase of the electrolyser’s cathode, leading to an increased efficiency of the overall electrolyzer. Image Credit: IIT-Istituto Italiano di Tecnologia. At posting the full research article is open access. Click here.

Hydrogen is considered as a sustainable energy vector, alternative to fossil fuels. But not all hydrogen is the same when it comes to environmental impact. Indeed, the main way hydrogen is produced nowadays is through the methane steam reforming, a fossil fuel-based process that releases carbon dioxide (CO2) as a by-product. The hydrogen produced by this process is classified as “grey” (when CO2 is release into the atmosphere) or “blue” (when CO2 undergoes capture and geological storage).

To significantly reduce emissions to zero by 2050 these processes must be replaced with more environmentally sustainable ones that deliver “green” (i.e. net-zero emissions) hydrogen. The cost of “green” hydrogen critically depends on the energy efficiency of the setup (the electrolyzer) that splits water molecules into hydrogen and oxygen.

The researchers from the joint team of this discovery have developed a new method that guarantees greater efficiency than currently known methods in the conversion of electrical energy (the energy bias exploited to split water molecules) into the chemical energy stored in the hydrogen molecules that are produced. The team has developed a concept of catalyst and have used renewable energy sources, such as the electrical energy produced by a solar panel.

Yong Zuo and Michele Ferri from the Nanochemistry Group at IIT in Genoa noted, “In our study, we have shown how it is possible to maximize the efficiency of a robust, well-developed technology, despite an initial investment that is slightly greater than what would be needed for a standard electrolyzer. This is because we are using a precious metal such as ruthenium.”

The researchers used nanoparticles of ruthenium, a noble metal that is similar to platinum in its chemical behavior but far less expensive. Ruthenium nanoparticles serve as the active phase of the electrolyser’s cathode, leading to an increased efficiency of the overall electrolyzer.

Sebastiano Bellani and Marilena Zappia from BeDimensional, commercial experts involved in the discovery explained, “We have run electro-chemical analyses and tests under industrially-significant conditions that have enabled us to assess the catalytic activity of our materials. Additionally, theoretical simulations allowed us to understand the catalytic behavior of ruthenium nanoparticles at the molecular level; in other words, the mechanism of water splitting on their surfaces. Combining the data from our experiments with additional process parameters, we have carried out a techno-economic analysis that demonstrated the competitiveness of this technology, when compared to state-of-the-art electrolysers.”

Ruthenium is a precious metal that is obtained in small quantities as a by-product of platinum extraction (30 tonnes per year, as compared to the annual production of 200 tonnes of platinum) but at a lower cost (18.5 dollars per gram as opposed to 30 dollars for platinum). The new technology involves the use of just 40 mg of ruthenium per kilowatt, in stark contrast with the extensive use of platinum (up to 1 gram per kilowatt) and iridium (between 1 and 2.5 grams per kilowatt, with iridium price being around 150 dollars per gram) that characterize proton-exchange membrane electrolysers.

By using ruthenium, the researchers at IIT and BeDimensional have improved the efficiency of alkaline electrolysers, a technology that has been used for decades due to its robustness and durability. For example, this technology was on board of the Apollo 11 capsule that brought humanity to the moon in 1969. The new family of ruthenium-based cathodes for alkaline electrolysers that has been developed is very efficient and has a long operating life, being therefore capable of reducing the production costs of green hydrogen.

The researchers concluded, “In the future, we plan to apply this and other technologies, such as nanostructured catalysts based on sustainable two-dimensional materials, in up-scaled electrolysers powered by electrical energy from renewable sources, including electricity produced by photovoltaic panels.”

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OK then. Not a lot said about the hydrogen production per energy unit. Which at the costs involved in this field might not be an issue until much further along.

What is really interesting is the cost comparison third paragraph up. Almost seven times the platinum for something less than twice the price. This is info worth keeping in mind.

Lets suppose this technology is market ready. 30 metric tons isn’t a huge supply. But 40 mg per kilowatt of output vs. a full gram is going to be a huge incentive. The iridium comparison is simply a shock. One wonders where the ruthenium is going to come from.


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