High-efficiency compound semiconductor solar cells can now be printed on flexible, plastics.
Chemistry provides a route to selective binding and extraction of radioactive cesium.
Enzymes originating from marine sponges were intentionally altered to create a new enzyme that can make semiconductors in artificial cells.
House-of-Cards structure leads to improved zeolite catalyst.
Visualization of electron pair binding confirms predictions about how high temperature superconductivity works.
New scalable, high power energy storage possible with carbon-electrolyte slurries.
Novel, liquid-less design promises to improve long-term stability and durability of dye-sensitized solar cells while hitting high efficiency marks.
Understanding how chemical vapors interact leads to better production equipment and increased lighting efficiency.
Overcoming a fundamental dilemma in making polymers that combine strength and toughness with spontaneous healing capability.
New catalyst structures for fuel cells in vehicles improve activity and stability compared to commercial platinum counterparts.
Adding nanostructured regions to boost LED light output.
Current-carrying nanotubes heat up nearby materials but not themselves, indicating a new path to energy-efficient electronics.
