Scientists at TU Delft have unlocked a key quantum effect in graphene without using any magnetic fields, paving the way for ...

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 ...

Why do electrons favor one spin over another in twisted environments? A newly developed system lets us explore this quantum bias with clarity.

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 and technology ...

Controlling electron spin. The standard method for controlling electron spin is electron spin resonance (ESR), which involves applying oscillating radiofrequency magnetic fields to the qubits.

A new platform for engineering chiral electron pathways offers potential fresh insights into a quantum phenomenon discovered by chemists—and exemplifies how the second quantum revolution is fostering ...

Could the future of clean energy hinge on the spin of a single electron? A new scientific review suggests it might.

Controlling electron spin. The standard method for controlling electron spin is electron spin resonance (ESR), which involves applying oscillating radiofrequency magnetic fields to the qubits.

A new review titled "Single-Electron Spin Qubits in Silicon for Quantum," published in Intelligent Computing, highlights the latest advances, challenges and future prospects of silicon spin qubits ...

The electron’s spin is rapidly converted into information contained in the helicity of the emitted photons, enabling a seamless integration of magnetization dynamics with photonic technologies. This ...

By using photons and electron spin qubits to control nuclear spins in a two-dimensional material, researchers have opened a new frontier in quantum science and technology, enabling applications ...

More information: Guangchong Hu et al, Single-Electron Spin Qubits in Silicon for Quantum Computing, Intelligent Computing (2025). DOI: 10.34133/icomputing.0115.