Moving four relatively large protons to where they are needed is easier if you build a path, as is being done by scientists at the Center for Molecular Electrocatalysis.
When it comes to driving hydrogen production, a new catalyst built at PNNL can do what was previously shown to happen only in nature: store energy in hydrogen and release that energy on demand.
Dr. Wendy Shaw is one of 31 distinguished young researchers from the United States selected by the National Academy of Sciences to attend the first Indonesian-American Frontiers of Science symposium
Twisting and pinching slow a catalyst's ability to generate energy from hydrogen, according to scientists at PNNL's Center for Molecular Electrocatalysis.
Dr. Donghai Mei and Dr. Roger Rousseau, PNNL, and Dr. Wei-Xue Li, Dalian Institute of Chemical Physics, have organized a symposium to connect across the various divides in catalysis
Looking to nature for their muse, researchers at PNNL have used a common protein to guide the design of a material that can make energy-storing hydrogen gas.
Scientists at PNNL's Center for Molecular Electrocatalysis and Villanova University designed a nickel-based complex that more than doubled previously reported hydrogen gas production rates and increased the energy efficiency of the reaction
To design catalysts for fuel cells and other devices, design their ligands to facilitate the movement of protons, according to Dr. Daniel DuBois and Dr. Morris Bullock at PNNL.
In an invited review article in the MRS Bulletin, scientists from the Center for Molecular Electrocatalysis discuss the role and need to control proton movement in potential solar devices.
Scientists at PNNL discuss options for storing solar, wind, and other intermittent power supplies as part of a new video featured on the Public Broadcasting System
PNNL researchers have benchmarked a number of commonly used density functional theory (DFT) and electron-correlated molecular orbital theories in their ability to describe the free energy profile for H2Â oxidation/evolution
New results reported in Chemical Communications describe the synthesis, structure, and catalytic reactivity of a nickel complex that is the fastest molecular electrocatalyst for oxidation of hydrogen.
A new book edited by PNNL's Dr. Morris Bullock summarizes the progress and challenges of designing catalysts from less expensive, more abundant metals.