Chicago Quantum Exchange adds three new corporate partners focused on enabling quantum technologies
The Chicago Quantum Exchange has added three new corporate partners to its growing network: Classiq, Lake Shore Cryotronics, and Oxford Instruments.
The three companies develop processes, tools, instruments and software that enable next-generation quantum technologies. Together, the Chicago Quantum Exchange and its corporate partners advance the science and engineering that are necessary to build and scale quantum technologies and develop practical applications, while working to expand career opportunities for the next generation of quantum-ready scientists and engineers.
“Classiq, Lake Shore Cryotronics, and Oxford Instruments all play key roles in helping scientists and engineers be productive at the interface between quantum information science and technology,” said David Awschalom, the Liew Family Professor in Molecular Engineering and Physics at the University of Chicago, senior scientist at Argonne, director of the Chicago Quantum Exchange, and director of Q-NEXT, a Department of Energy Quantum Information Science Center. “We look forward to working together and advancing our capabilities in the field.”
Lake Shore Cryotronics provides high-performance cryogenic temperature instruments and sensors; low-vibration cryostats for ultra-high vacuum environments; cryogenic wafer probe stations; and complete materials characterization solutions for exploring and developing next-generation quantum materials.
“Lake Shore Cryotronics is proud to be part of the CQE and its work bringing together universities, national labs, and industry partners to achieve the critical mass of capability needed to overcome challenges that will move quantum technology from the lab to practical use,” said Scott Yano, Chief Technical Officer for Lake Shore Cryotronics.
Oxford Instruments is a leading provider of high-technology products and services to the world’s top industrial companies and scientific research communities. The company is at the forefront of enabling solutions for quantum technologies development, providing solutions to cool systems to milli-Kelvin temperatures, observe quantum entanglement in photons, and fabricate and characterize qubits and novel quantum materials.
“Oxford Instruments is excited to be part of such an impactful and innovative group, and we look forward to working along with all of the Chicago Quantum Exchange member institutions and partners,” said Bill Keating, president of Oxford Instruments America.
Classiq’s Quantum Algorithm Design platform is revolutionizing quantum software development. Companies use the platform to solve real-world problems with quantum circuits that could not be built otherwise, and the company’s patented technology automatically transforms high-level functional models into optimized quantum circuits for a wide range of back-end systems. This can turn months into minutes of work and makes it possible to harness the true power of today’s and tomorrow’s computers.
“Fulfilling the promise of the quantum computing revolution requires more than just great hardware. It requires intelligent software that allows creating sophisticated algorithms that solve real-world problems,” says Yuval Boger, chief marketing officer at Classiq. “Classiq is excited to join the Chicago Quantum Exchange and collaborate with other leading companies in creating a complete solution to the burning issues of the researchers and engineers that are harnessing quantum.”
About the Chicago Quantum Exchange:
The Chicago Quantum Exchange (CQE) is an intellectual hub for advancing the science and engineering of quantum information between the CQE community, across the Midwest, and around the globe. A catalyst for research activity across its member and partner organizations, the CQE is based at the University of Chicago and is anchored by the U.S. Department of Energy’s Argonne National Laboratory and Fermi National Accelerator Laboratory, the University of Illinois Urbana-Champaign, the University of Wisconsin-Madison, and Northwestern University.
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