Electricity doesn’t flow the way most people imagine. Instead of electrons rushing through wires like water in a pipe, energy moves as an electromagnetic field surrounding the wire. The real current ...

In a metal like copper, however, the outer electrons swim around freely and are shared by all the atoms. That’s why ...

Electricity feels instant, but its movement is a dance of charged particles, magnetic fields, and invisible forces. When a switch is flipped, electrons don’t race through the wire — energy does, ...

MIT scientists uncovered direct evidence of unconventional superconductivity in magic-angle graphene by observing a distinctive V-shaped energy gap. The discovery hints that electron pairing in this ...

MIT researchers uncovered clear evidence of unconventional superconductivity in magic-angle twisted trilayer graphene.

At SEMICON India ’25, TANAKA PRECIOUS METALS leaders Yutaka Ito, Natalie Abe, and Satoshi Teshima share how ultra-pure bonding wires and sustainable recycling are redefining semiconductor materials — ...

Industry analysts estimate that U.S. data center power demand will double over the next five years. By 2030, global data centers could consume as much electricity as the entire nation of Japan. That ...

Superconductivity occurs when electrons pair up, rather than scattering apart as they do in normal conductors or in everyday ...

Electricity powers our lives, including our cars, phones, computers, and more, through the movement of electrons within a ...

A light pulse redirects electrons in an ultrathin layered material, creating a stable new state without heat or damage and ...

Scientists at TU Wien found that electrons need specific “doorway states” to escape solids, not just energy. The insight ...