Light moving through a tiny silicon structure does not look dramatic. It slips down narrow waveguides etched onto a chip, ...

A physics professor at the University of Nevada, Reno and his colleagues have identified quantum geometry as an opportunity to increase the superconducting temperature of two-dimensional ...

The performance of quantum computers could cap out after around 1,000 qubits, according to a new analysis published in the ...

Researchers at the University of Central Florida have demonstrated a method for generating scalable quantum entanglement on ...

Scientists uncovered hidden geometry that distorts electron paths like gravity bends light, advancing quantum materials for faster data and lossless conduction. (Nanowerk News) How can data be ...

Random geometry and quantum gravity represent interwoven themes at the frontier of modern mathematical physics. These fields examine the stochastic nature of geometric structures that underpin quantum ...

Large-scale quantum computers are waiting in the wings. One of the main reasons we don't have them yet is because quantum ...

Quantum metric spaces extend the classical notion of metric spaces into the noncommutative realm by utilising operator algebras and associated seminorms to capture geometric structure in settings ...

In a remarkable leap for quantum physics, researchers in Japan have uncovered how weak magnetic fields can reverse tiny electrical currents in kagome metals—quantum materials with a woven atomic ...

A single beam of entangled light, generated by equipment found in laboratories around the world, has been concealing one of ...

How can data be processed at lightning speed, or electricity conducted without loss? To achieve this, scientists and industry alike are turning to quantum materials, governed by the laws of the ...