A new approach creates microscale bioreactors for studying complex reactions for energy production and storage.
Study changes perception on how acids behave in water.
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.
Direct measurement of an elusive but critical combustion molecule leads to more accurate models of ignition chemistry.
Surface plasmons move at nearly the speed of light and travel farther than expected, possibly leading to faster electronic circuits.
Spectroscopy combined with theory and computation determines the interaction between carbon dioxide and water.
Commercialized nanopost array platform reveals metabolic changes in individual cells due to environmental stress.
Using computational methods, scientists tailor and adapt proteins to mine uranium from seawater.
New nanoscale thermal imaging technique shows heat building up inside microprocessors, providing new information to help solve heat-related performance issues.
New models reveal the impact of competing processes on helium bubble formation in plasma-exposed tungsten.
Pairs of precisely tuned X-ray pulses uncover ultrafast processes and previously unmapped structures.
