WEST LAFAYETTE, Ind. — By using photons and electron spin qubits to control nuclear spins in a two-dimensional material, researchers at Purdue University have opened a new frontier in quantum science ...

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

An electron has a spin degree of freedom, meaning that it not only holds a charge but also acts like a little magnet. In spintronics, a key task is to use an electric field to control electron spin ...

Controlling the quantum state of electrons is crucial for quantum information processing, including new types of superpowerful computers and unbreakable cryptography. Scientists have known for a while ...

In order to scale quantum computers, more qubits must be added and interconnected. However, prior attempts to do this have ...

A chip-scale interface entangles light and electronic states without cryogenic cooling, bringing quantum networking hardware ...

The fact is that all electrons are the same as each other and the object is what changes. We explain why you’re not falling through your chair right now using one simple fact, and one object. The fact ...

Electrons are proficient little magicians. They seem to flit about an atom without tracing a particular path, they frequently appear to be in two places at once, and their behavior in silicon ...

A new study reveals how trillionth-of-a-second light pulses strongly deflect magnetization by exploiting orbital-spin ...

As published Monday (Aug. 15) in Nature Materials, the research team used electron spin qubits as atomic-scale sensors, and also to effect the first experimental control of nuclear spin qubits in ...