QphoX B.V., a Dutch quantum technology startup that is developing leading frequency conversion systems for quantum applications, Rigetti Computing, Inc., a pioneer in full-stack quantum-classical computing, and Qblox, a leading innovator in quantum control stack development, today announced that their joint research demonstrating the ability to readout superconducting qubits with an optical transducer was published in Nature Physics.

Q-CTRL, the global leader in quantum control infrastructure software, today announced the opening of its newest office in San Francisco, further strengthening its U.S. presence and reinforcing its position as a dominant player in the global quantum industry.

The future of tin-based qubits is brighter thanks to breakthrough work by Stanford University researchers supported through a quantum research center led by the U.S. Department of Energy’s (DOE) Argonne National Laboratory.

The University of Strathclyde has partnered with the National Physical Laboratory (NPL) and Quantum Motion to develop new ways to overcome the challenges of running quantum control electronics in extremely cold conditions.

A team of physicists and engineers at the CU Boulder has discovered a new way to measure the orientation of magnetic fields using what may be the tiniest compasses around—atoms. The group’s findings could one day lead to a host of new quantum sensors, from devices that map out the activity of the human brain to others that could help airplanes navigate the globe. The new study, published this month in the journal Optica, stems from a collaboration between physicist Cindy Regal and quantum engineer Svenja Knappe.

Now, engineers at the University of Pennsylvania School of Engineering and Applied Science (Penn Engineering) have utilized quantum sensors to realize a groundbreaking variation of nuclear quadrupolar resonance (NQR) spectroscopy, a technique traditionally used to detect drugs and explosives or analyze pharmaceuticals.

Researchers at the University of Chicago Pritzker School of Molecular Engineering have realized a new design for a superconducting quantum processor—aiming at a potential architecture for the large-scale, durable devices the quantum revolution demands.

SEALSQ Corp ("SEALSQ" or "Company"), a company that focuses on developing and selling Semiconductors, PKI, and Post-Quantum technology hardware and software products, today announced that 2025 is expected to be a landmark year for SEALSQ and its parent company WISeKey International Holding Ltd. (“WISeKey”) as they advance their leadership in quantum technologies. SEALSQ is focusing on breakthroughs in post-quantum algorithms and semiconductor innovations, while WISeKey is reinforcing its Public Key Infrastructure (PKI) with a quantum root key to address the challenges of the quantum era.

Researchers at the UChicago Pritzker School of Molecular Engineering (UChicago PME) have realized a new design for a superconducting quantum processor, aiming at a potential architecture for the large-scale, durable devices the quantum revolution demands.

To maintain and expand the United States’ leadership in the global race for quantum technology, U.S. Sen. Maria Cantwell (D-Wash.), Chair of the Senate Committee on Commerce, Science and Transportation, Sen. Todd Young (R-Ind.), member of the Committee, Sen. Dick Durbin (D-Ill.) and Sen. Steve Daines (R-Mont.) introduced the National Quantum Initiative Reauthorization Act, which would authorize $2.7 billion in federal funding to accelerate quantum research and development at federal science agencies for the next five years.