Q-NEXT collaborator and UChicago grad student Chloe Washabaugh creates high-performance qubits from designer molecules. Not only is she expanding the applications of quantum devices, but she’s also working to attract a diverse audience to quantum.
Researchers have begun to use magnets to entangle qubits, the building blocks of quantum computers; the simple technique could unlock complex capabilities.
At the 2023 AAAS Meeting in Washington, DC, experts discuss how the scientific community can make quantum information science more accessible and reach a wider base of innovators.
The Argonne Quantum Foundry is meeting a critical need for quantum science by providing a robust supply chain of materials for quantum devices and systems.
The postdoctoral researcher, a collaborator with the Q-NEXT quantum research center, develops high-tech materials to deliver photon packages of quantum information.
Following a free, advance screening of the movie in downtown Chicago, leading experts in quantum science discussed the quantum realm in Marvel’s universe and in ours.
A research team supported by the Q-NEXT quantum research center demonstrates a new way to use quantum sensors to tease out relationships between microscopic magnetic fields.
The roadmap serves as a guide for research and development in quantum interconnects, devices that link and distribute quantum information between systems and across distances to enable quantum computing, communications and sensing.
Researchers affiliated with the Q-NEXT quantum research center show how to create quantum-entangled networks of atomic clocks and accelerometers — and they demonstrate the setup’s superior, high-precision performance.