Pouring Fire on Fuels at the Nanoscale
https://www.oist.jp/news-center/news/2015/8/6/pouring-fire-fuels-nanoscale[font face=Serif][font size=5]Pouring Fire on Fuels at the Nanoscale[/font]
6 Aug 2015
[font size=3]There are no magic bullets for global energy needs. But fuel cells in which electrical energy is harnessed directly from live, self-sustaining chemical reactions promise cheaper alternatives to fossil fuels.
To facilitate faster energy conversion in these cells, scientists disperse nanoparticles made from special metals called noble metals, for example gold, silver and platinum along the surface of an electrode. These metals are not as chemically responsive as other metals at the macroscale but their atoms become more responsive at the nanoscale. Nanoparticles made from these metals act as a catalyst, enhancing the rate of the necessary chemical reaction that liberates electrons from the fuel. While the nanoparticles are being sputtered onto the electrode they squash together like putty, forming larger clusters. This compacting tendency, called sintering, reduces the overall surface area available to molecules of the fuel to interact with the catalytic nanoparticles, thus preventing them from realizing their full potential in these fuel cells.
Research by the
Nanoparticles by Design Unit at the Okinawa Institute of Science and Technology Graduate University (OIST), in collaboration with the SLAC National Laboratory in the USA and the Austrian Centre for Electron Microscopy and Nanoanalysis, has developed a way to prevent noble metal nanoparticles from compacting, by encapsulating them individually inside a porous shell made of a metal oxide. The OIST researchers published their findings in
Nanoscale. Their work has immediate applications in the field of nano-catalysis for the manufacturing of more efficient fuel cells.
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More core-shell combinations can be tried using our technique, with metals cheaper than Palladium for instance, like Nickel or Iron. Our results show enough promise to continue in this new direction, said Vidyadhar Singh, the papers first author, and postdoctoral fellow under the supervision of Prof. Mukhles Sowwan, the director of OISTs Nanoparticles by Design Unit, who was also a corresponding author of the paper.[/font][/font]