Catalysts are the unsung heroes of chemistry, accelerating reactions used to make fertilizers, fuels and consumer products. Our work aims to make catalysts more efficient and reduce the use of fossil fuels.
Scientists used a combination of four techniques, represented here by four incoming beams, to reveal in unprecedented detail how a single atom of iridium catalyzes a chemical reaction.
(Greg Stewart/SLAC National Accelerator Laboratory)
Stanford and SLAC engineers observed electrons at work during catalytic reactions. Their findings challenge long-held theories about some catalysts, opening the door to new...
More than a dozen energy-storage companies have streamlined access to research facilities and expertise at SLAC under a new cooperative R&D agreement with CalCharge.
In this lecture, SLAC’s Ryan Coffee explains how researchers are beginning to use pattern recognition and machine learning to study chemical reactions at the...
The SLAC and Stanford professor and SUNCAT director is being honored for groundbreaking work in catalysis, which promotes chemical reactions in thousands of industrial...
By observing how hydrogen is absorbed into individual palladium nanocubes, Stanford materials scientists have detailed a key step in storing energy and information in...
Stanford and SLAC engineers observed electrons at work during catalytic reactions. Their findings challenge long-held theories about some catalysts, opening the door to new or improved renewable energy applications.
More than a dozen energy-storage companies have streamlined access to research facilities and expertise at SLAC under a new cooperative R&D agreement with CalCharge.
In this lecture, SLAC’s Ryan Coffee explains how researchers are beginning to use pattern recognition and machine learning to study chemical reactions at the level of atoms and molecules with the LCLS X-ray laser.
The SLAC and Stanford professor and SUNCAT director is being honored for groundbreaking work in catalysis, which promotes chemical reactions in thousands of industrial processes.
By observing how hydrogen is absorbed into individual palladium nanocubes, Stanford materials scientists have detailed a key step in storing energy and information in nanomaterials.