Quantum computing technology is complex, getting off the ground and maturing. There is promise of things to come. potentially changing the computing paradigm.

Physicists found why holes move slower than electrons in silicon: not defects, but higher intrinsic mass, supporting ...

A new study uncovers how tiny misalignments in quantum communication links can quietly undermine security. Quantum key distribution (QKD) is a next generation method for protecting digital ...

Imagine traveling through a city where the streets themselves change shape depending on how fast you drive down them. For ...

Lasers and quantum electronics represent a transformative amalgam of quantum mechanics and electromagnetic technology that underpins much of modern scientific and industrial innovation. Central to ...

Quantum Motion has established a permanent European base with the opening of new offices in Spain, marking a significant step in its global expansion strategy.

A team of researchers has found one of the missing pieces of the hardware puzzle that allows quantum computers to function at ...

An associate professor in the Department of Physics, Lomsadze uses powerful laser-based tools to capture ultrafast events in quantum materials, work that could shape the future of technology.

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 ...

Nonlinear optical dynamics—intensity-dependent response of light upon interaction with materials under high-intensity light sources—are of huge significance in modern photonics, finding applications ...

In a study published in Nature Communications, a team of scientists led by Rice University's Qimiao Si predicts the existence of flat electronic bands at the Fermi level, a finding that could enable ...

The vast problem-solving potential of quantum computing, along with its deep ties to artificial intelligence, health care, ...