Capturing and Converting CO2 in a Single Step
Researchers computationally design a cheap, efficient catalyst that captures carbon dioxide and creates a chemical building block.
Researchers computationally design a cheap, efficient catalyst that captures carbon dioxide and creates a chemical building block.
First-of-its-kind measurements provide insights on reactions that could one day turn sunlight and water into fuels.
Using computational methods, scientists tailor and adapt proteins to mine uranium from seawater.
Experimental turbulence model matches the magnetic field amplification seen within the remains of a supernova.
Realistic computational view of how atom stretches informs microscopic description of nuclear energy production.
Advances in simulating water molecules in droplets reveal surfaces that may be resistant to ice formation.
Pairs of precisely tuned X-ray pulses uncover ultrafast processes and previously unmapped structures.
Careful tuning of a surface at the nanoscale could lead to robust materials for solar panels, other uses.
Innovative materials adsorb carbon dioxide via an unprecedented cooperative insertion mechanism.
Atomic-scale defects in graphene are shown to selectively allow protons to pass through a barrier that is just one carbon atom thick.
New nanoscale thermal imaging technique shows heat building up inside microprocessors, providing new information to help solve heat-related performance issues.
New approach to design and assemble tiny composite materials could advance energy storage.