Crypto news

17.06.2026
18:41

Atom Computing and Nu Quantum join forces to build scalable quantum networks

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Two leading players in the field of quantum computing — Atom Computing and Nu Quantum — have signed a memorandum of understanding aimed at overcoming one of the main barriers to practical quantum systems: scaling. The partners intend to combine Atom Computing's neutral atom platform with Nu Quantum's advanced photonic networking solutions, which dynamically reconfigure for specific tasks.

The primary focus of the collaboration is the creation of integrated photonic switches, the development of qubit-photon entanglement technologies, and the modeling of distributed fault-tolerant architectures. This is not just abstract research: the goal is to connect multiple quantum processors into unified modular systems capable of performing computations beyond laboratory experiments.

Key challenge — transitioning from isolated quantum chips to networks where qubits can exchange information over distance while maintaining quantum coherence. Photonic channels serve as a natural bridge here, as light particles interact minimally with the environment, which is critical for the stability of quantum states.

Nu Quantum is already developing hardware for creating photon-based quantum networks, while Atom Computing owns one of the most promising platforms for scaling — neutral atoms allow thousands of qubits to be held in optical traps with high precision. The synergy of these technologies could drive the creation of the first commercially significant quantum computing clusters.

My expert assessment: This collaboration is a logical step in the evolution of the quantum industry. While many competitors struggle to increase the number of qubits in a single processor, Atom Computing and Nu Quantum are betting on a distributed architecture. If they manage to solve the problem of quantum switching at the photonic level, we could see the first modular quantum systems within the next 3–5 years, which will fundamentally change the landscape of high-performance computing.