Q-Next Quantum Center Renewed for Five Years

A significant portion of this work is happening at SLAC in partnership with Stanford University. Among other priorities, this group is focusing on the development of the first high-bandwidth quantum network that connects systems regardless of their qubit type, whether atomic, superconducting or solid-state.

“We’re building on the strong foundation we’ve laid over the past five years to take on our renewed mission — harnessing distributed entanglement to show what’s possible with scalable quantum platforms,” said incoming Q-NEXT Director and Argonne scientist Martin Holt. “By uniting quantum technologies across optical networks, we will pave the way for systems capable of revolutionizing how we process, transmit and receive information.”

Quantum partnerships

Q-NEXT brings together a strong network of partners: two DOE national laboratories, 11 leading universities, and six tech companies. This cross-sector collaboration ensures that the center’s work is both innovative and practical, bridging the gap between scientific discovery and real-world application. Universities contribute expertise in quantum sensing and communication, while industry partners provide access to state-of-the-art prototypes and manufacturing capabilities. Together, Q-NEXT partners form a vibrant ecosystem that drives progress in quantum science.

“We envision quantum systems that work across chip-to-chip, lab-to-lab and city-to-city scales,” said Q-NEXT Deputy Director Jennifer Dionne, who is a professor of materials science and engineering and, by courtesy, of radiology at Stanford University and SLAC National Accelerator Laboratory. “We’re excited to advance a shared set of hardware, software and protocols to make quantum networks and sensors efficient and practical.”

Science goals

Q-NEXT’s renewed efforts will focus on three scientific goals:

1. Communication – developing quantum communication networks that link devices across metropolitan areas. Q-NEXT aims to demonstrate algorithms that run across multiple remote, connected quantum processors.
2. Sensing – using quantum entanglement to achieve unprecedented precision in sensing applications. Q-NEXT will demonstrate real-world uses, such as in medicine and navigation, as well as foundational scientific discoveries in gravitation and quantum mechanics where quantum entanglement gives a clear advantage in sensing and measurement.
3. Materials – developing new approaches to integrating materials that can be scaled for industry use. Q-NEXT will tackle the most important challenges involved in merging distinct quantum materials systems with advanced functionality and integrating them into practical quantum devices.

Q-NEXT will pursue its goals through large-scale, team-based projects that combine materials science, device engineering and quantum physics theory. By leveraging world-class science facilities, Q-NEXT aims to deliver breakthroughs that will shape the future of quantum technology. These include the Argonne semiconductor and SLAC superconducting quantum foundries, SLAC’s Linac Coherent Light Source (LCLS) and Stanford Synchrotron Radiation Lightsource (SSRL), Argonne’s Advanced Photon Source (APS), and several other DOE Office of Science user facilities.

The planned quantum network development is being tested by connecting sites at SLAC and Stanford, using superconducting quantum devices like transducers at each of the fiber ends, fabricated at the SLAC-based quantum foundry. 

“SLAC has the only superconducting quantum foundry that is co-located with light sources and experimental facilities that enable a better understanding of quantum materials at the time scales needed to understand their properties,” said associate lab director for SLAC’s Quantum Science and Technology Initiative Lisa Bonetti.

Read more from Argonne National Lab here.

This work was supported by the U.S. Department of Energy Office of Science National Quantum Information Science Research Centers as part of the Q-NEXT center.