Quantum computers, systems that process information leveraging quantum mechanical effects, could reliably tackle various ...

Researchers at Kyushu University have shown that careful engineering of materials interfaces can unlock new applications for ...

Researchers report a room-temperature organic microcavity where two different forms of spin–orbit coupling act together to ...

Atomic-scale defects in 2D materials show terahertz spin splitting, pointing to robust spin qubits and single-photon emitters at higher temperatures.

As AI and IoT drive explosive global data growth, energy-efficient information devices have become critical for sustainability. Kyushu University researchers demonstrate that inserting an atomic-scale ...

Spin–orbit coupling (SOC) in semiconductor heterostructures, particularly in quantum wells and two-dimensional electron gases (2DEGs), has emerged as a pivotal mechanism in spintronics and quantum ...

In the rapidly evolving field of quantum computing, silicon spin qubits are emerging as a leading candidate for building scalable, fault-tolerant quantum computers. A new review titled ...

Flipping ferroelectric polarization reverses bimeron topology in a two-dimensional magnet, allowing voltage pulses alone to ...

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