Scientists coax simple molecules into forming complex three-dimensional structures for faster, more energy-efficient electronics.
Designed molecules will provide positive impacts in energy production by selectively removing unwanted ions from complex solutions.
A new computational technique greatly simplifies the complex reaction networks common to catalysis and combustion fields.
These enhanced tools will accelerate gene discovery and characterization, vital for new forms of fuel production.
Aircraft data show that ice particles are smaller and fall faster than models had assumed; correcting this issue in models improves simulation of deep, raining cloud systems.
Data from three Arctic measurement sites show how clouds, temperature, and water vapor impact the Arctic surface energy budget, which could enhance future warming and sea ice melt.
Water table depth and groundwater flow are vital to understanding the amount of water that plants transmit to the atmosphere.
A new fast and robust algorithm for computing stellarator coil shapes yields designs that are easier to build and maintain.
Fast imaging of frozen argon pellets enables measurement of fast electrons formed during disruption for first time.
Heating the core of fusion reactors causes them to develop sheared rotation that can improve plasma performance.
Scientists discover new signposts in the quest to determine how matter from the early universe turned into the world we know today.
Electric and magnetic properties of a radioactive atom provide unique insight into the nature of proton and neutron motion.
