Watching Catalysts Evolve in 3-D
Scientists reveal structural, chemical changes as nickel-cobalt particles donate electrons, vital for making better batteries, fuel cells.
Scientists reveal structural, chemical changes as nickel-cobalt particles donate electrons, vital for making better batteries, fuel cells.
Swirling soup of matter’s fundamental building blocks spins ten billion trillion times faster than the most powerful tornado, setting new record for “vorticity.”
New studies of behaviors of particles containing heavy quarks shed light into what the early universe looked like in its first microseconds.
First complete picture of genetic variations in a natural algal population could help explain how environmental changes affect global carbon cycles.
The genetic material of Porphyra umbilicalis reveals the mechanisms by which it thrives in the stressful intertidal zone at the edge of the ocean.
Seven-year study explains how packets of light are exchanged when protons meet electrons.
The newly upgraded CEBAF Accelerator opens door to strong force studies.
Confined within tiny carbon nanotubes, extremely cold water molecules line up in a highly ordered chain.
Scientists design outstanding catalysts by controlling the composition and shape of these tiny plate-like structures on the nanoscale.
Scarce compound is key for cellular metabolism and may help shape microbial communities that affect environmental cycles and bioenergy production.
The quest for solar cell materials that are inexpensive, stable, and efficient leads to a breakthrough in thin film organic-inorganic perovskites.
Scientists invent a new approach to creating ordered patterns of nitrogen-vacancy centers in diamond, a promising approach to storing and computing quantum data.