Less is more: Efficient Hydrogen Production with Less Precious Metals

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In a step towards sustainable energy, a team of researchers at the University of Twente led by Dr Marco Altomare have demonstrated a new method to reduce the use of precious metals such as platinum in green hydrogen production without sacrificing performance. The researchers published their findings in the Wiley VCH scientific journal Advanced Functional Materials .

The world urgently needs to transition to sustainable energy sources to combat climate change and the energy crisis. Green hydrogen is an important step, and a large-scale hydrogen economy needs efficient, compact, and resilient technologies.

Polymer electrolyte membrane (PEM) water electrolysers and fuel cells use precious metal catalysts such as platinum and iridium to make hydrogen production and conversion as efficient as possible. However, these catalysts are expensive and scarce and thus limit large-scale development of hydrogen technologies. Accordingly, by 2026, the U.S. Department of Energy (Doe) wants to achieve performances that are about 5-10 times higher than current cells, with less than 20% of the currently used amount of these metals (currently, about 3 mg/cm2 as total loading of platinum and iridium) - a grand scientific and technological challenge.

No loss in performance

Studying platinum as a model catalyst, the team of Dr Marco Altomare, in collaboration with partners from Erlangen and Pavia (Italy), combined physical vapour deposition (PVD) and controlled thermal treatments (known as solid-state dewetting) to create highly active and durable electrodes with minimized amounts of precious metal. -According to our preliminary lab experiments, with our approach, we can potentially reduce the amount of precious catalyst needed by five times. All without loss in H2 generation-, points out Shreyas Harsha, the PhD researcher at the forefront of the project.

Dr Marco Altomare adds: -Our method is completely chemical-free, hence safer and with no waste of precious catalyst precursor, and it is scalable - in fact, similar thin film deposition methods are already used at scale in various industrial applications, and our facilities at the University of Twente are already suited to coat catalysts layers on surfaces of up to a few 100 cm2.-

Further reduction

The team of Dr Marco Altomare now aims to achieve the next target, in collaboration with Dutch research centres and companies. The researchers want to test their electrodes under industry-relevant conditions, to demonstrate and validate efficient and stable water electrolysis operation with noble metal loadings reduced to less than 0.5 mg/cm2. Achieving this breakthrough holds great promise for the future of green hydrogen production and sustainable energy.

Shreyas Harsha is a PhD candidate in the Photocatalytic Synthesis group (PCS) at the University of Twente. Under the supervision of Dr Marco Altomare, Shreyas currently researches the development of nanostructured electrodes through the application of physical vapour deposition and solid-state dewetting methods for electrochemical hydrogen generation.

Dr Marco Altomare is currently an assistant professor in the Department of Chemical Engineering , at the Faculty of Science and Technology (S&T) and MESA+ institute of the University of Twente (UT). His team, specialized in materials science for electrochemical conversion, published the above findings in a recent article, titled -Dewetting of Pt Nanoparticles Boosts Electrocatalytic Hydrogen Evolution Due to Electronic Metal-Support Interaction- , in the Wiley VCH scientific journal Advanced Functional Materials ., also featured in the Wiley VCH virtual special issue -Hot Topic: Water Splitting-.

10.1002/adfm.202403628

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