A team at UNIGE has uncovered a geometric structure once thought to be purely theoretical at the core of quantum materials, opening the door to major advances in future electronics. How can ...

Superconductors promise loss-free electricity, but most only work at extreme cold. Hydrogen-rich materials changed that—yet their inner workings remained hidden because they only exist under enormous ...

The dynamic of charging isn’t as straightforward as pain at the gas pump. It’s also different from Americans’ suffering over ...

By using mechanical force and a common amino acid, researchers have demonstrated a way to make graphene both electrically ...

In physics and materials science, the term "spin chirality" refers to an asymmetry in the arrangement of spins (i.e., the ...

For decades, physicists taught that superconductivity and magnetism could not share the same space. One state should destroy ...

A standard reference thermoelectric module (SRTEM) for objectively measuring thermoelectric module performance has been ...

A “standard reference thermoelectric module (SRTEM)*” for objectively measuring thermoelectric module performance has been ...

Scientists develop metal-organic framework composites that convert nitrogen to ammonia using renewable electricity, offering ...

The CGM acts as a critical interface between the galaxy and the cosmic web — the filamentary network of matter that forms the ...

Programmable photonics promise faster and more energy-efficient computing than traditional electronics by using light to transmit signals. However ...

Under pressures that would crush a car into scrap, a long standing mystery about how some of the most extreme superconductors actually work is finally giving way. By combining new measurement tricks ...