The company has developed a proof-of-principle prototype that will enable quantum computers to be connected to a quantum network via a Qubit-Photon Interface (QPI). This interface is being described as the equivalent of today’s Network Interface Cards (NICs), which connect every single computer in a data centre together and have enabled the Cloud and AI markets.
To have a useful quantum computer that can, for example, accurately simulate the world at the atomic level, quantum computers need to be 1000x larger than they are today and, inevitably, they need to move beyond a single-QPU towards a distributed quantum computer made of hundreds of QPUs and at data centre scales, just like the cloud and AI supercomputers.
The efficient transfer of quantum information between matter and light at the quantum level is the biggest challenge to scaling quantum computers, and the specific issue that the QPI addresses.
Nu Quantum’s QPI has been designed for atomic qubits, and the first version of it has been integrated into Infleqtion’s trapped atom vacuum system and successfully tested under ultra-high vacuum, the harsh conditions under which qubits will need to operate.
The next step will be to demonstrate controlled high-efficiency coupling between an individual atom stimulated to emit a photon - tackling one of the most long-standing technical challenges in the industry to date.
Dr. Claire Le Gall, VP of Technology at Nu Quantum, said, “Everyone acknowledges that an efficient interface between qubits and photons -’matter and light’ is critical to scaling quantum computing. It's been really exciting to work with Infleqtion on this project! We've successfully married our QPI-technology (qubit photon interface) with their ultra-high vacuum cold-atom cells. We are pleased with the progress our QPI has made through early-stage testing, and we look forward to further refining its performance. We're excited to move on to the next phase of our R&D, where we aim for ~100x improvement in quantum networking speed.”
“Collaboration is essential to advancing the quantum computing field, and working with partners like Nu Quantum allows us to explore new avenues in connecting qubits to quantum networks,” said Dr. Marco Palumbo, Director of Business Development UK, at Infleqtion. “While this is a proof of concept, we look forward to continued experimentation and development in pursuit of scalable quantum technologies."
Enhancing qubit-photon entanglement is the first step towards modular and scalable distributed quantum computers but creating qubit-photon entanglement with high-fidelity and high-rate is the single biggest technical challenge preventing the modular scaling of quantum computer, communication and sensor networks.
The QPI aims to significantly improve entanglement rates over current lab methods, with the goal of enabling industrial-scale deployment.
Nu Quantum’s solution uses optical microcavities to enhance the coupling between light and matter. Nanostructured mirrors, fabricated using the company’s proprietary process, are assembled together with micron-level precision, and the distance between them actively stabilised to < 80 pm.
Open microcavities allow enhanced interaction between the qubits and the networking photons, whilst keeping all material far enough away to protect the delicate qubit state from outside noise and keeping access for control lasers.
This is, according to Nu Quantum, the first industrial demonstration of a passively aligned optical microcavity with a tunable lock to guarantee operation at the qubit resonance.
Several engineering challenges have been overcome including low noise locking optics and the electronics has been developed in a robust, deployable form; cavity alignment has remained stable under high temperature vacuum bakeout, while the materials used in the QPI construction have not adversely affected the quality of the vacuum.
Nu Quantum’s aim is to eventually allow any Neutral Atom qubit provider to plug into Nu Quantum’s networking infrastructure, enabling modular scaling: from individual quantum processing units (QPUs) to data centre-scale Distributed Quantum Computers.
