Scientists map atomic-level changes in the components of a running internal combustion engine using neutron techniques.
Biological production of acetone and isopropanol by gas fermentation captures more carbon than it releases.
A material with a disordered rock salt structure could help make batteries safer, faster-charging, and able to store more energy
Understanding Ions’ Subtle Molecular-Level Interactions Allows Scientists to Tune the Melting Point
A new catalyst design meets cost, activity, and durability goals by leveraging ultralow loadings of platinum with platinum-free supports.
A first-of-its-kind computer simulation reveals self-healing cement for geothermal and oil and gas wells performs better than originally thought.
Window material repeatedly switches from being see-through to blocking the heat and converting sunlight into electricity.
Iron may be more valuable than platinum. Sometimes.
Precise control of surface chemistry leads to efficient, stable perovskite solar cells.
New binding molecules formed a protective layer after charging and discharging, making a promising battery component more stable.
Switchgrass cultivated during a year of severe drought inhibited microbial fermentation and resulting biofuel production.
The quest for solar cell materials that are inexpensive, stable, and efficient leads to a breakthrough in thin film organic-inorganic perovskites.
