PsiQuantum today announces Omega, a quantum photonic chipset purpose-built for utility-scale quantum computing. Featured in a newly published paper in Nature, the chipset contains all the advanced components required to build million-qubit-scale quantum computers and deliver on the profoundly world-changing promise of this technology. Every photonic component is demonstrated with beyond-state-of-the-art performance. The paper shows high-fidelity qubit operations, and a simple, long-range chip-to-chip qubit interconnect – a key enabler to scale that has remained challenging for other technologies. The chips are made in a high-volume semiconductor fab, representing a new level of technical maturity and scale in a field that is often thought of as being confined to research labs. PsiQuantum will break ground this year on two datacenter-sized Quantum Compute Centers in Brisbane, Australia and Chicago, Illinois.

In a significant milestone for scalable quantum computing, Quantum Motion, a UK-based quantum computing scale-up founded by academics from University College London and Oxford University, has demonstrated rapid, large-scale characterisation of quantum devices fabricated using commercial semiconductor processes. Quantum Motion has designed a silicon chip featuring an integrated array of 1024 quantum dots on an area of less than 0.1mm² and validated them in less than 5 minutes—at least 100 times faster than the current state of the art. The chips were manufactured by GlobalFoundries, a leading semiconductor manufacturer, with whom Quantum Motion has announced a partnership to develop quantum processors based on a scalable silicon platform.

Lightmatter has announced Passage M1000, a groundbreaking 3D Photonic Superchip designed for next-generation XPUs and switches. The Passage M1000 enables a record-breaking 114 Tbps total optical bandwidth for the most demanding AI infrastructure applications.

GlobalFoundries (GF) today announced plans to create a new center for advanced packaging and testing of U.S.-made essential chips within its New York manufacturing facility. Supported by investments from the State of New York and the U.S. Department of Commerce, the first-of-its-kind center aims to enable semiconductors to be securely manufactured, processed, packaged and tested entirely onshore in the United States to meet the growing demand for GF’s silicon photonics and other essential chips needed for critical end markets including AI, automotive, aerospace and defense, and communications.

Together with 24 German research institutions and companies under the coordination of Forschungszentrum (FZ) Jülich, Fraunhofer IPMS is working on an integrated German quantum computer based on superconducting quantum chips and with improved error rates. Halfway through the project, the first demonstrator can now be put into operation.