Getting the Most from Ultra-Large Climate Datasets
Project provides tools for advanced data analysis and visualization.
Project provides tools for advanced data analysis and visualization.
Using artificial nanostructures to control the properties of light could play a prominent role in the future of computing.
Predicted materials could economically produce high-purity methane from natural gas systems and separate methane from coal mine ventilation systems.
Nano-structuring may help superconductors overcome a decades-long barrier to use in more powerful motors and magnets.
Designing protein assemblies whose interactions can be manipulated to respond to a single environmental cue.
Advances in how we calculate optical properties of semiconductors shorten the path to improved solar cells and other optoelectronic devices.
High magnetic fields reveal the existence of nitrogen superclusters.
A phase change at absolute zero temperature may provide key insights into the decades-old mystery of high-temperature superconductivity.
Exploiting the self-organizing nature of atoms to block heat transfer and improve thermal-to-electrical energy conversion.
Nano-porous metal oxide coatings on carbon fiber dramatically enhance the electrical storage capacity for supercapacitors.
First observation of key intermediate state in the conversion of one photon to two electrons.
Tropical atmospheric data used to test climate model accuracy.