Researchers at Argonne National Lab have recently developed a process to improve the efficiency of producing hydrogen to run cars such as this prototype, which was developed at the Oakridge National Lab. | Photo courtesy of Oak Ridge National Laboratory.
It’s said that breaking up is hard to do. That’s undoubtedly true. But when the lightning does strike, the electricity is lasting.
What’s true for affairs of the heart also holds true for the affairs of hydrogen, as researchers at the Office of Science’s Argonne National Laboratory have recently shown. Hydrogen is an important, energetic element, which is used in a variety of applications ranging from making semiconductors to powering fuel cells. However, it’s also a difficult, expensive one to produce in pure molecular form. Hydrogen usually shows up as a pair of hydrogen atoms (H2).
As Nenad Markovic, a senior chemist at Argonne, noted, “People understand that once you have hydrogen, you can extract a lot of energy from it, but they don’t realize just how hard it is to generate that hydrogen in the first place.” Markovic led research at Argonne that recently showed a cheaper, cleaner way to produce pure hydrogen, one that begins with a breakup.
Specifically, the team took a look at breaking up water, taking the H2 out of the H2O. Water electrolyzers already do so, typically using special metals like platinum to speed up, or catalyze, the reaction. However, in addition to being costly, platinum is also a better maker-upper than breaker-upper -- it is better at fixing single hydrogen atoms up than separating them from water in the first place. For more about catalysts, see: “Seven things you might not know about catalysis."
So Markovic and his team added clusters of a metallic complex, nickel-hydroxide, to the platinum catalyst. It ripped the water molecule apart and freed the hydrogen atoms to come together aided by the platinum catalyst. Altogether, it drove the reaction at about ten times its previous rate.
What’s more, this research gave the scientists new insight into materials with virtually no defects, what are known as “single crystal systems.” These materials, or at least their theoretical ideals, give scientists models to test their predictions against, and to make predictions on how materials might behave in the real world. In the case of Argonne, the modeled catalysis matched up with the real-world analysis, which may suggest ways to accelerate other reactions observed and theorized in basic science and energy research.
Breaking up is never easy, and making up is often hard. But as Argonne and the Office of Science have shown, when it happens, it can be electric, and the positive benefits are likely to be long-lasting.