A new approach creates microscale bioreactors for studying complex reactions for energy production and storage.
Researchers computationally design a cheap, efficient catalyst that captures carbon dioxide and creates a chemical building block.
The proton's primary building blocks, up and down quarks, are produced more often than strange quarks in scattering experiments.
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.
Realistic computational view of how atom stretches informs microscopic description of nuclear energy production.
Atomic-scale defects in graphene are shown to selectively allow protons to pass through a barrier that is just one carbon atom thick.
Researchers determine the reaction pathway to how soot and other toxic components form in combustion systems.
Scientists shed new light on a proton's spin, refining our understanding of nuclear physics.
New structures could accelerate progress toward faster computing and high-security data transfer across fiber optic networks.
Nanowire-based design incorporates two semiconductors to enhance absorption of light.
