Welinq, a leader in quantum networking technology, has launched the first commercial quantum memory designed specifically for quantum data centers with world-record performance. Quantum computing is reaching a turning point: with more than 100 individual quantum computers deployed in dedicated infrastructures, the next challenge is networking them into scalable, high-performance architectures.

Rice University physicists have discovered a phase-changing quantum material — and a method for finding more like it — that could potentially be used to create flash like memory capable of storing quantum bits of information, or qubits, even when a quantum computer is powered down.

UChicago Pritzker Molecular Engineering researchers created a "quantum-inspired” revolution in microelectronics, storing classical computer memory in crystal gaps where atoms should be.

As AI's energy demands grow due to massive datasets, quantum memory offers a promising solution by processing and storing data more efficiently. Recent research shows that quantum memory can reduce the computational steps needed, cutting both time and energy use. This could make AI more sustainable, as less data would be required to achieve the same results, significantly lowering its energy footprint. While still developing, quantum memory has the potential to reshape data processing and storage across industries.

ICFO researchers have obtained a world record degree of indistinguishability between two photons coming from two dissimilar quantum nodes when no detections are discarded. These results pave the way towards future heterogeneous quantum networks.

Rice University physicists have discovered a phase-changing quantum material — and a method for finding more of it — that could potentially be used to create flash like memory capable of storing qubits, even when a quantum computer is powered down.

In a landmark advancement for quantum networking, Welinq, a pioneering company in quantum interconnects, is delighted to announce the awarding of a highly-competitive EIC Transition grant of 2.5M€.

In new research published in the Journal of the American Chemical Society, University of Illinois Urbana Champaign materials science & engineering professor Daniel Shoemaker and graduate student Zachary Riedel have used density functional theory (DFT) calculations to identify possible europium (Eu) compounds to serve as a new quantum memory platform.

A research team led by Prof. GUO Guangcan, Prof. SHI Baosen and Prof. DING Dongsheng from the University of Science and Technology of China (USTC) of the Chinese Academy of Sciences (CAS) achieved 25-dimensional quantum memory with high efficiency in cold atomic ensemble.

Researchers at the University of Basel have built a quantum memory element based on atoms in a tiny glass cell. In the future, such quantum memories could be mass-produced on a wafer.