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

Quantum materials can behave in surprising ways when many tiny spins act together, producing effects that don’t exist in ...

Add Yahoo as a preferred source to see more of our stories on Google. Quantum computers promise to solve problems far beyond the reach of classical machines, from simulating new materials to ...

Scientists from the National University of Singapore (NUS) have discovered that atomic-scale substitutional dopants in ...

Collective behavior is an unusual phenomenon in condensed-matter physics. When quantum spins interact together as a system, ...

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 ...

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

Researchers have designed a new device that can efficiently create multiple frequency-entangled photons, a feat that cannot be achieved with today's optical devices. The new approach could open a path ...

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 ...

This interaction could help explain both why quantum processes can occur within environments like the brain and why we lose consciousness under anesthesia.

Quantum systems can simulate molecular interactions at a level of fidelity that classical computers cannot achieve. They can ...