In hybrid materials, “hot” electrons live longer, producing electricity, not heat, for solar cells.
Defects in liquid crystals act as guides in tiny oceans, directing particle traffic.
New binding molecules formed a protective layer after charging and discharging, making a promising battery component more stable.
Built from the bottom up, nanoribbons can be semiconducting, enabling broad electronic applications.
Direct writing of pure-metal structures may advance novel light sources, sensors and information storage technologies.
Scientists reveal structural, chemical changes as nickel-cobalt particles donate electrons, vital for making better batteries, fuel cells.
Scientists combine biology, nanotechnology into composites that light up upon chemical stimulation.
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.
A new class of plant-specific genes required for flowering control in temperate grasses is found.
Demonstrating the microfluidic-based, mini-metagenomics approach on samples from hot springs shows how scientists can delve into microbes that can’t be cultivated in a laboratory.
First complete picture of genetic variations in a natural algal population could help explain how environmental changes affect global carbon cycles.
