The phenomenon where electron spins align in a specific direction after passing through chiral materials is a cornerstone for ...

This schematic illustrates how regulating electron spin states through six key strategies—including defect engineering, valence modulation, and magnetic field application—can optimize catalytic ...

Abstract The interaction between electron spin and molecular chirality plays a fundamental role in quantum phenomena with significant implications for ...

When quantum spins interact, they can produce collective behaviors that defy long-standing expectations. Researchers have now shown that the Kondo effect behaves very differently depending on spin ...

The twisting direction of metal nanoparticles is controlled to be right- or left-handed by adding chiral molecules, which are adsorbed onto the particle surface, during the electrochemical reduction ...

Diamonds with certain optically active defects can be used as highly sensitive sensors or qubits for quantum computers, where the quantum information is stored in the electron spin state of these ...

One of the most intriguing ideas for qubits is electrons that float above the surface of liquid helium at a temperature of ...

A potential breakthrough from Japan may address one of the key obstacles facing this ...

The physics department at UC Santa Barbara houses its own powerful particle accelerator that accelerates electrons to 99.4% of the speed of light: The Sherwin Group’s ability to produce short and ...