The force that enables nanosize crystals to grow could be used to design new materials.
Scarce compound is key for cellular metabolism and may help shape microbial communities that affect environmental cycles and bioenergy production.
Microbes leave a large fraction of carbon in anoxic sediments untouched, a key finding for understanding how watersheds influence Earth’s ecosystem.
New strategy significantly increases the production and secretion of biofuel building block lipids in bacteria able to grow at industrial scales.
The quest for solar cell materials that are inexpensive, stable, and efficient leads to a breakthrough in thin film organic-inorganic perovskites.
New supercomputing capabilities help understand how to cope with large-scale instabilities in tokamaks.
For the first time, scientists modeled the spontaneous bifurcation of turbulence to high-confinement mode, solving a 35-year-old mystery.
A new uranium-based metal-organic framework, NU-1301, could aid energy producers and industry.
Calculations of a subatomic particle called the sigma provide insight into the communication between subatomic particles deep inside the heart of matter.
Scientists invent a new approach to creating ordered patterns of nitrogen-vacancy centers in diamond, a promising approach to storing and computing quantum data.
Antibody’s molecular structure reveals how it recognizes the virus.
State-of-the-art mass spectrometer delivers unprecedented capability to scientists.
