Vibrations Raise the Critical Temperature for Superconductivity
Scientists reveal that coupling between electrons and atomic vibrations play a key role in this vexing phenomenon.
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.
Near the onset of superconductivity, continuous exchange of electrons occurs between distinct, liquid-like magnetic phases in an iron-based superconductor.
Scientists synthesized a theoretically-predicted material with unusual current-carrying properties that could open the door for next-generation electronics.
Generating and moving small, stable magnetic islands at room temperature could be the ticket to more energy-efficient electronics.
Bio-based molecular machines mechanically extrude tiny tubes and form networks, aiding in the design of self-repairing materials.
Major milestone in molecular electronics scored by Molecular Foundry and Columbia University team.
Tiny “match-head” wires act as built-in light concentrators, enhancing solar cell efficiency.
For the first time, electron tomography reveals the 3D coordinates of individual atoms and defects in a material.
A new, dime-sized light source will lead to novel spectrometers for the next generation of scientific discoveries.
Researchers have attained superlubricity, the near absence of friction, at a carbon-silica interface using nanodiamonds wrapped in graphene flakes.
Low-fatigue material remembers its shape, despite being transformed over 10 million times, could upgrade solar devices.