Quick Takeaways
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MIT and the Novo Nordisk Foundation Quantum Computing Programme (NQCP) signed a four-year collaboration to enhance quantum computing hardware research through shared laboratories and knowledge exchange.
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The partnership will focus on developing fault-tolerant quantum computing hardware and algorithms addressing life-science challenges, with MIT receiving approximately $2.55 million in funding.
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Key objectives include demonstrating consistent operation of advanced quantum systems, a crucial step towards practical applications in technology and science.
- The collaboration aims to leverage the expertise of leading researchers, enhancing Denmark’s capabilities and accelerating breakthroughs in quantum computing relevant to life sciences.
Testing Spooky Action at a Distance: A New Era in Quantum Computing Collaboration
Researchers at MIT recently embarked on an ambitious journey in quantum computing. The university signed a four-year collaboration agreement with the Novo Nordisk Foundation Quantum Computing Programme (NQCP) at the Niels Bohr Institute in Copenhagen. This agreement aims to enhance quantum computing hardware research.
Both institutions will establish identical quantum laboratories on their campuses. Therefore, this setup will promote seamless cooperation and knowledge exchange. Students can also benefit from this collaboration through exchange programs.
William Oliver, a leading professor in electrical engineering and computer science at MIT, highlighted the significance of this partnership. He stated, “To realize the promise of quantum computing, we must learn how to build systems that are robust, reproducible, and extensible.” The program allows researchers to innovate faster by sharing personnel and ideas. They will conduct parallel experiments and compare results.
Oliver’s team will lead the research funded by 18 million Danish kroner, approximately $2.55 million. They will focus on developing fault-tolerant quantum computing hardware. Additionally, the research will explore quantum algorithms addressing real-world problems in life sciences.
Maria Zuber, MIT’s presidential advisor for science and technology policy, emphasized the importance of state-of-the-art hardware for consistent operation. She said, “The goal of this collaboration is to demonstrate this system behavior, an important step in the path to practical application.”
Collaboration stands at the forefront of innovation in today’s fast-moving technological landscape. Anantha Chandrakasan, MIT’s chief innovation and strategy officer, noted that partnerships with other universities accelerate research. “The support from the Novo Nordisk Foundation ensures that leading experts can focus on advancing findings that impact the real world,” he added.
Morten Kjaergaard, an associate professor at the Niels Bohr Institute, expressed optimism about their work. He remarked, “This project allows Danish research in quantum computing hardware to learn from the best.” Their joint research will focus on developing next-generation fault-tolerant quantum hardware.
Peter Krogstrup, CEO of NQCP, echoed this sentiment. He expressed excitement about collaborating with Oliver’s innovative team. Additionally, he highlighted the strategic focus of developing paths that harness quantum computing for life sciences.
This vibrant collaboration between MIT and the NQCP signals a noteworthy development in the field of quantum computing. Researchers are poised to push boundaries and uncover new possibilities that could revolutionize technology and improve lives.
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https://news.mit.edu/2024/testing-spooky-action-distance-0731
