New Insight on a Familiar Glow
A new approach to investigating green fluorescent protein provides a vital tool for unraveling molecular-level details of processes important in biology and light harvesting for energy use.
A new approach to investigating green fluorescent protein provides a vital tool for unraveling molecular-level details of processes important in biology and light harvesting for energy use.
Reactions with this extremely rare element could reveal previously unknown trends, benefiting studies of new nuclear reactor fuels.
Demonstration of room temperature, single photon emission in doped carbon nanotubes opens a new path toward quantum information technologies.
Using tools that enable nuclear physics research into the heart of matter, scientists created a material for applications from aerospace to solar panels.
The neutron skin of the nucleus calcium-48 is much thinner than previously thought.
Herbivore digestion involves a large variety of enzymes that break woody plants into biofuel building blocks.
Penetrating x-rays can image defects and phase changes during battery charging and discharging.
Researchers use surface-sensitive signals to atomically resolve the structure of a rough surface.
Ultrafast laser shots act like dopants to create new electronic properties in materials.
Scientists reveal that coupling between electrons and atomic vibrations play a key role in this vexing phenomenon.
Novel technique accurately distinguishes rare material property linked to improving sensors and computers.
Pre-designed molecular building blocks provide atomic-level control of the width of graphene nanoribbons.