Quantum computers will be our best tool to counter some of the world’s most difficult challenges including health, climate and energy challenges.
Advancing drug design and molecular discovery with unmatched precision.
Enabling greener materials and cleaner energy breakthroughs.
Solving complex problems to improve global systems and efficiency.
Quantum computing's current scale-up paradigm is hitting a wall and only network-enabled scale-out can unlock the next frontier of quantum compute power.
Our blueprint for quantum computing scale-out
Nu Quantum is on a mission to integrate novel photonic hardware and interconnects to weave entanglement between quantum processors. The resulting scale-out enables the Entanglement Fabric: a modular, scalable and fault-tolerant architecture.
Qubit-photon interfaces (QPIs) are the bridge between quantum processors and the network, enabling light from qubits to couple efficiently to the networking layer. Our technology is adaptable to different qubit types and we collaborate with leading quantum computing companies to integrate our prototypes into their hardware systems.
We develop optical switching and detection technology that can create and distribute quantum entanglement across computing nodes. Built on photonic integrated circuits (PICs), our hardware is designed to meet the requirements of speed, efficiency, and low-loss necessary for quantum computing.
Our 19-inch rack-mount Quantum Networking Units (QNUs) host photonic technology to distribute quantum entanglement across processors. Reconfigurable entanglement links are dynamically orchestrated and maintained through our proprietary networking protocols for distributed computation and control.
Datacentre-scale quantum computing power is unlocked by our networking technology, which weaves quantum processors together to form a distributed computer. With subsystems adaptable to different qubit types, our modular approach enables the development of upgradable systems and opens a scalable path to commercial quantum computing.
We explore quantum error-correction codes that exploit sparse, non-local connectivity and its reconfigurability to delineate efficient distributed quantum computing architectures.