Dec
29
Solar Powered Hydrogen Production Advances
December 29, 2015 | Leave a Comment
Scientists at the Energy Department’s National Renewable Energy Laboratory (NREL) announced advances have been made toward affordable photoelectrochemical (PEC) production of hydrogen. PEC is solar energy driving a semiconductor coated with a catalyst that for this example chemically splits hydrogen from water. The NREL work shows that molecular catalysts can be as highly active as the precious metal-based catalysts.
Surface modification strategies for the p-GaInP2 photoelectrodes. Image Credit: NREL. Click image for the largest view.
The NREL scientists took a different approach to the PEC process of solar energy to split water into hydrogen and oxygen. The process requires special semiconductors for the PEC materials and catalysts to split the water. Previous work used precious metals such as platinum, ruthenium and iridium as catalysts attached to the semiconductors. A large-scale commercial effort using those precious metals wouldn’t be cost-effective, however, due to the costs of the rare metals.
The use of cheaper molecular catalysts instead of precious metals has been proposed, but these have encountered issues with stability, and were found to have a lifespan shorter than the metal-based catalysts.
The NREL researchers decided to examine molecular catalysts outside of the liquid solution they are normally studied in to see if they could attach the catalyst directly onto the surface of the semiconductor. They were able to put a layer of low cost titanium dioxide (TiO2) on the surface of the semiconductor and bond the molecular catalyst to the TiO2.
Their work showed molecular catalysts can be as highly active as the precious metal-based catalysts.
The research, “Water Reduction by a p-GaInP2 Photoelectrode Stabilized by an Amorphous TiO2 Coating and a Molecular Cobalt Catalyst,” has been published in Nature Materials. Jing Gu and Yong Yan are lead authors of the paper. Contributors James Young, Nathan Neale and John Turner are all with NREL’s Chemistry and Nanoscience Center. Contributor K. Xerxes Steirer is with NREL’s Materials Science Center.
Turner pointed out that although the molecular catalysts aren’t as stable as the metal-based catalysts, PEC systems are shut down each evening as the sun sets. That leaves time to regenerate a molecular catalyst.
“Hopefully you would not have to do that every day, but it does point to the fact that low stability but highly active catalysts could be viable candidates as a long-term solution to the scalability issue for PEC water splitting systems,” Turner said.
Its an encouraging sign to see the research get around the huge cost barrier presented by precious metal use. The work is another step in solving the biggest cost issue. But there are other less expensive issues to work out indicating this field is coming along as intellectual prowess and creativity pay off. But this technology will need the same problem solved as all the other hydrogen technologies: cheap tight storage.
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