READING, UK – June 19, 2025 – Oxford Quantum Circuits (OQC), a global leader in quantum computing solutions spun out from Oxford University, today announces research that could dramatically accelerate the path to commercially viable quantum computers. The Company’s latest research demonstrates a new approach to quantum error-detection that could reduce the massive hardware requirements which have slowed the development of practical quantum computing applications.

Today’s quantum computers face a fundamental obstacle: their individual computing units (qubits) are error-prone. While current quantum processors have enough computing power to outperform classical computers on specific tasks, their error rates limit general practical usefulness. To create reliable quantum computers capable of running extraordinarily complex operations, the industry has traditionally believed it would need to build machines with thousands of physical qubits that allow for the engineering of a much smaller number of reliable, error-corrected logical qubits to enable computation. Only then can quantum computers be relied on for widespread commercial applications.

OQC’s breakthrough centers on its patented dual-rail dimon qubit technology, the Dimon approach, which uses a novel “dual-rail” hardware design to detect and suppress errors at the individual qubit level – something that previous quantum systems couldn’t achieve efficiently. In new research published on arXiv, the Company demonstrates a critical milestone of reproducible error suppressed qubits; slashing the hardware overheads required for quantum error corrected logical qubits, bringing fault-tolerant quantum computing within reach using far fewer physical qubits than previously thought necessary.

The dual-rail dimon qubit outlines a clear path for OQC’s architecture to maintain quality and stability while scaling up, addressing one of the biggest technical hurdles facing the quantum computing industry’s transition from experimental devices to practical systems. This breakthrough has the potential to fundamentally change the economics of quantum computing by dramatically reducing the infrastructure and hardware costs needed to achieve commercially-useful quantum computation. Rather than requiring massive quantum processors with millions of qubits, OQC’s approach could enable powerful quantum applications with significantly smaller and more affordable systems. This research demonstrates that through intentional design, superconducting qubits can be made significantly more robust with minimal increase to its size and complexity. OQC’s Dimon approach enables OQC’s strategy for hardware-efficient quantum error correction to realise rapidly scalable, low-error quantum computation, which is reflected in their recently published comprehensive roadmap.

In the 20th century, the information technology revolution took off when classical computing technology evolved beyond enormously expensive and bespoke engineered custom systems that could not be reliably operated except by a very small number of highly trained specialists, which made computation expensive and scarce. OQC’s breakthrough represents a major step toward the Company’s objective of bringing about a parallel transition in quantum – by building an affordable quantum computing infrastructure by 2028 that can reliably perform millions of quantum operations for a variety of users, OQC can unlock quantum computing’s potential in fraud detection, classification, financial modeling,and other transformative commercial applications.

About OQC
Oxford Quantum Circuits (OQC) is pioneering the quantum-accelerated world, delivering enterprise-grade quantum systems designed for commercial and strategic advantage. As Europe’s first Quantum-Compute-as-a-Service provider and the only company integrating quantum in commercial data centres they bring quantum capability to the heart of financial and national infrastructure. Their application-optimised compute empowers customers in finance, security, and defence to solve intractable problems—reshaping industries and strengthening sovereign advantage.

Read the full research on arXiv here.
Read the research blog here.