In a study published online in Nature, a research team led by Prof. PAN Jianwei, Prof. CHEN Yuao, and Prof. YAO Xingcan from the University of Science and Technology of China (USTC) of the Chinese Academy of Sciences has, for the first time, observed the antiferromagnetic phase transition within a large-scale quantum simulator of the fermionic Hubbard model (FHM).

After development and testing with leading government and private sector partners, SandboxAQ is officially announcing AQNav, a breakthrough technology designed for navigation across air, land and sea when Global Positioning Satellite (GPS) systems are jammed or not available. To date, AQNav has logged more than 200 flight-hours and more than 40 sorties across multiple regions of the world on four different aircraft types, ranging in size from single-engine planes to large military transport aircraft.

A highly sensitive diamond quantum magnetometer utilizing nitrogen-vacancy centers can achieve millimeter-scale resolution magnetoencephalography (MEG), as reported by scientists from Tokyo Tech. The novel magnetometer, based on continuous-wave optically detected magnetic resonance, marks a significant step towards realizing ambient condition MEG and other practical applications.

Q-CTRL, the global leader in quantum infrastructure software, announced successful field trials of a new generation of quantum-assured navigation solutions validated to outperform comparable conventional alternatives in challenging real-world settings. This marks the first achievement of commercial quantum advantage for any of the recently posed applications of quantum technology, cementing Q-CTRL’s role as the dominant leader in the quantum sector.

Fermioniq is honoured to have been part of a collaboration led by Quantinuum – together with TUM, MCQST, Caltech and EPFL – which demonstrated the capabilities of Quantinuum’s H2 quantum computer for simulating quantum magnetism at the limit of classical methods. This work is an important step on the path towards achieving quantum advantage for a task of practical utility.

Recently, a group of researchers led by Prof. QU Zhe from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences, together with Prof. CHANG Tay-Rong from National Cheng Kung Universityhas discovered a novel way to achieve spin-valve effects using kagome quantum magnets.

Frequency Electronics, Inc. (“FEI” or the “Company”) (NASDAQ-FEIM), a leading provider of precision timing and frequency technology, today announced it has been awarded a subcontract from Leidos to develop a next-generation Nitrogen Vacancy (NV) Diamond Magnetometer.

Led by D-Wave, an international collaboration including researchers from UBC’s Blusson QMI has achieved a major milestone in quantum annealing, pushing computing beyond classical limits to solve complex magnetic material simulation problems for materials discovery. The study was published in Science.

In the coming months, the Defense Innovation Unit’s (DIU’s) Transition of Quantum Sensing (TQS) program will demonstrate the military utility of quantum sensors to address strategic Joint Force competencies like positioning, navigation, and timing (PNT), as well as anomaly detection. Significant progress on the scientific understanding and product development of quantum sensors, offering the promise of significant improvements in precision, accuracy, and sensitivity compared to classical sensors, is being made, and these solutions, as well as the supporting companies advancing these technologies, are ready to proceed forward.

Empa researchers from the nanotech@surfaces laboratory have experimentally recreated another fundamental theoretical model from quantum physics, which goes back to the Nobel Prize laureate Werner Heisenberg. The basis for the successful experiment was a kind of “quantum Lego” made of tiny carbon molecules known as nanographenes. This synthetic bottom-up approach enables versatile experimental research into quantum technologies, which could one day help drive breakthroughs in the field.