Fraunhofer EMFT and Oxford Quantum Circuits (OQC) have formed a strategic partnership to accelerate superconducting quantum technology industrialization. This combination between Fraunhofer’s advanced fabrication skills and OQC’s system-level quantum understanding advances quantum computing. The united effort creates a scalable and producible quantum computing path.
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From Lab Bench to Factory Floor
The quantum industry is fast evolving and approaching a new era where the capacity to scale to produce quantum processors consistently, reliably, and at industrial quality rather than just the number of qubits is increasingly what defines success. In order to achieve scalability, the superconducting community is embracing industrial-grade tooling and fabrication standards, as evidenced by the collaboration between OQC and Fraunhofer EMFT.
John M. Martinis, the 2025 Nobel Prize winner in Physics, has emphasised the significance of utilising semiconductor technologies for superconducting systems. By integrating superconducting quantum devices with industry-standard, CMOS-compatible technologies that serve as the cornerstone of global semiconductor manufacturing, OQC and Fraunhofer are taking on this challenge head-on. Investors, consumers, and legislators are more confident that quantum technology may develop successfully inside the same frameworks that created modern computing as a result of this alignment with CMOS-compatible methods.
The Fabless Future of Quantum
This strategic partnership is an intentional step towards OQC’s adoption of a fabless quantum model. This methodology separates the actual fabrication process from top-tier design and system engineering. The goal of this strategy is to enable the same kind of worldwide scalability that revolutionized the conventional semiconductor business.
This view was expressed by Connor Shelly, OQC’s VP of Materials Science and Device Engineering, who said, “The future of scale is a fabless world.” He said OQC can achieve this goal by combining cutting-edge industrial processes with deep fabrication expertise that has spurred quantum innovation through its relationship with Fraunhofer.
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Fraunhofer’s Role: Bridging Research and Manufacturing
Fraunhofer EMFT contributes a special capacity to the collaboration: converting intricate quantum research into CMOS-compatible, scalable procedures. Fraunhofer’s Quantum CPU Pilot Line will play a key role in converting superconducting qubit research into industrial-grade, reproducible manufacturing processes.
This pilot line essentially creates a bridge that brings quantum technology firmly into the realm of industrial manufacturing by showing how well-established semiconductor infrastructure can directly enable the synthesis of superconducting qubits. The director of Fraunhofer EMFT, Prof. Christoph Kutter, expressed his enthusiasm by saying that they are “thrilled to deploy the Fraunhofer EMFT quantum pilot line as standard manufacturer of OQC quantum processing units.” He said Fraunhofer’s semiconductor processing expertise will benefit partners and the quantum computing sector by creating scalable quantum hardware.
One of the top organizations in the world for applied research is Fraunhofer-Gesellschaft, which has its headquarters in Germany. Prioritizing research on cutting-edge technologies and applying the findings to industry is central to its goal, which enhances Germany’s economic base and helps society at large.
Recent articles collectively show that Fraunhofer’s fabrication environment is capable of producing high-performance superconducting qubits using industrial-grade techniques, highlighting the maturity of their capabilities. The superconducting platform is now ready for scaling up via standard CMOS-compatible lines the very infrastructure that supports today’s global semiconductor supply chain the consistency seen in these results across several process nodes. The transition of OQC’s superconducting qubit technology to their CMOS-line was described as a “highly fascinating technological task and a prime example for bridging semiconductor research and industrial production” by Dr. Thomas Mayer, Project Lead at Fraunhofer EMFT.
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OQC’s Foundational Innovation
OQC’s hardware roadmap and system engineering are supported by thorough research that blends industrial practicality with scientific accuracy. The company’s potential to transition to a fabless model is supported by its ongoing efforts to push the frontiers of superconducting qubit development.
For instance, OQC investigated the use of high-purity sapphire substrates to enhance overall qubit quality and coherence in a recent paper published in Advanced Materials. Advanced machining capabilities were used in this study to enable the fabrication of sapphire-based Quantum Processing Units (QPUs) on a wafer scale. This effort effectively integrated basic research with a laser-like focus on improving the yield and quality of their devices.
Additionally, OQC has been studying a crucial component of superconducting qubits: the Josephson junction. This study describes junction tuning using a theoretical framework and evaluates barrier variation using sophisticated microscopy and electrical measurements. This fundamental work gives OQC the tools it needs to comprehend the crucial connection between junction repeatability and process factors at a manufacturing scale. Through important industrial collaborations like the one with Fraunhofer, OQC is laying the groundwork for quantum devices that can function at scale and be produced by developing both materials engineering and qubit architecture.
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Collaboration as the Catalyst
This all-encompassing collaboration is a reflection of a larger collective shift in the superconducting ecosystem, which is demonstrated by programs like Supreme and the increasing focus on inter-institutional cooperation and common standards. Fraunhofer EMFT and OQC both stress that scaling should be seen as a shared endeavor rather than a race to the top.
Open cooperation, an emphasis on reproducibility, and agreement on manufacturable technologies are necessary for the shift from research-scale quantum computing to industry-scale implementation. Shelly reaffirmed that scaling quantum computing is essentially a “ecosystem challenge” rather than just an engineering issue. He went on to say that synchronizing materials, procedures, and standards is necessary to realize the enormous impact that quantum computing is expected to have.
Next-generation superconducting qubits that can be produced in large quantities are made possible by the OQC–Fraunhofer partnership. This is seen to be a crucial step in realizing quantum deployment in the real world. With the possibility for deeper technical transfers, more collaborative publications, and the addition of other industrial partners in the future, the cooperation marks a sea change in the development of quantum computing. In the end, this partnership signifies the critical transition of superconducting technology from the lab to a scalable, commercial reality.
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