Xanadu and Corning Collaborate to Develop Scalable Fibre Interconnects for Photonic Quantum Computing

Xanadu and Corning have entered a collaboration to advance fibre interconnects for photonic quantum computing, aiming to develop low-loss solutions. Based in Toronto and New York, respectively, the companies leverage Xanadu’s expertise in ultra-low-loss photonic chips and Corning’s innovation in optical fibres.

Their goal is to enable fault-tolerant, universal photonic quantum computers at scale. Xanadu demonstrated this potential with Aurora, a fibre-networked system using 35 chips and 13 km of fibre, currently handling 12 qubits but scalable to one million for fault tolerance. The partnership focuses on reducing optical loss through specialized fibres, which is crucial for scaling photonic quantum computing infrastructure.

Xanadu and Corning Collaborate on Fibre Interconnects for Photonic Quantum Computing

Xanadu, a leading photonic quantum computing company, has collaborated with Corning Incorporated, a global leader in fibre technology. This partnership aims to develop customized fibre solutions for connecting photonic chips in quantum computers, enhancing their scalability and efficiency.

The collaboration leverages Xanadu’s expertise in ultra-low-loss photonic chips and Corning’s advanced low-loss optical fibres. The goal is to create fault-tolerant, universal photonic quantum computers capable of handling large-scale computations. This initiative builds on Xanadu’s successful Aurora project, which utilized 35 photonic chips connected by 13 km of fibre, achieving a 12-qubit system with potential for scaling up to one million qubits.

Central to this effort is the development of fibre interconnects that minimize optical loss, crucial for maintaining performance as systems scale. Inna Krasnokutska from Xanadu emphasized the importance of reducing optical loss to achieve practical quantum computing applications.

Corning’s role involves designing and manufacturing fibre solutions optimized for photonic integrated circuits, addressing the stringent loss requirements necessary for scaling Aurora. This collaboration underscores the critical need for specialized fibre interconnects in advancing photonic quantum computing, highlighting the synergy between Xanadu’s innovation and Corning’s technological prowess.

Xanadus Aurora Project Demonstrates Scalability in Photonic Quantum Computing

The Aurora project represents a significant milestone in photonic quantum computing, demonstrating the feasibility of scaling interconnected photonic chips. By integrating 35 packaged photonic chips with 13 kilometers of optical fibre, Xanadu achieved a system capable of handling complex computations at scale while maintaining low optical loss.

The development of specialized fibre interconnects is critical for supporting large-scale quantum computing architectures. These interconnects must meet stringent requirements to ensure minimal signal degradation as data travels between chips. Corning’s role in designing optimized fibre solutions addresses these challenges, enabling the creation of fault-tolerant photonic quantum systems.

About Xanadu and Corning: Background and Missions

Xanadu is a leading photonic quantum computing company that develops advanced technologies to solve complex computational problems. Their Aurora project has demonstrated significant progress in scaling interconnected photonic chips, achieving a 12-qubit system with potential for scaling up to one million qubits.

Corning Incorporated is a global leader in fibre technology, known for its innovative solutions that support cutting-edge applications. In this collaboration, Corning is designing and manufacturing fibre solutions optimized for photonic integrated circuits, addressing the stringent loss requirements necessary for large-scale quantum computing architectures.

Together, Xanadu and Corning are advancing photonic quantum computing infrastructure, paving the way for more robust and efficient systems. Their partnership underscores the importance of minimizing optical loss in maintaining system integrity and scalability, leveraging cutting-edge fibre technologies to achieve practical quantum computing applications.