Paragraf and Archer Materials Partner on Graphene-Based Quantum Hardware

Paragraf and Archer Materials Partner on Graphene-Based Quantum Hardware Paragraf, a UK-based developer of graphene electronics, and Archer Materials, an Australian technology company specializing in quantum-enabling devices, have announced a cooperative research and development program. The collaboration focuses on leveraging graphene-based device platforms to develop next-generation quantum computing hardware. By combining Paragraf’s scalable graphene fabrication process—which grows high-quality graphene directly on semiconductor wafers—with Archer’s expertise in quantum architectures, the partners aim to develop new device structures for qubit detection and information processing. The technical core of the initiative involves researching novel graphene architectures for quantum measurement and control. Graphene is being targeted for these roles due to its high electronic mobility, low noise characteristics, and atomic-scale thickness, which are advantageous for interfacing with emerging quantum systems. The program seeks to transition these material properties into practical device prototypes, specifically focusing on graphene’s potential to improve the sensitivity and reliability of quantum sensors and detection modules. The partnership aligns with Archer Materials’ strategy of utilizing advanced materials to transition deep-tech research into commercially viable products. Archer contributes domain expertise in device physics and sensing applications to facilitate rapid iteration of designs tailored to specific quantum end-use requirements. This collaboration is expected to produce a pipeline of graphene-based technologies for markets in quantum computing and advanced sensing, utilizing Paragraf’s industry-compatible manufacturing platform as the foundational infrastructure. You can find the official announcement regarding the Paragraf and Archer Materials collaboration here. May 1, 2026 Mohamed Abdel-Kareem2026-05-02T13:57:08-07:00 Leave A Comment Cancel replyComment Type in the text displayed above Δ This site uses Akismet to reduce spam. Learn how your comment data is processed.