Website: [quantummotion.tech](https://quantummotion.tech) ### Introduction Quantum Motion, a UK-based quantum computing company, was founded in 2017 by Professor John Morton of University College London (UCL) and Professor Simon Benjamin of the University of Oxford. Headquartered in London, with additional operations in Oxford, the company focuses on developing scalable quantum computing technologies using silicon-based architectures. While specific employee counts are not publicly available as of the latest data, Quantum Motion operates as a private company and is not listed on any stock exchange, thus having no ticker symbol. The mission of Quantum Motion is to accelerate the development of fault-tolerant quantum computers by leveraging silicon technology, which is compatible with existing semiconductor manufacturing processes. This approach aims to reduce costs and enable scalability, positioning the company as a key player in the race to build practical quantum computing solutions for industries such as cryptography, drug discovery, and materials science. The company has emerged from academic research roots into a promising startup with significant potential in the quantum computing ecosystem. ### Key Products and Technology Quantum Motion is focused on developing quantum computing hardware and architectures, with an emphasis on silicon-based quantum processors. Below are details of their key technological focus areas: - **Silicon-Based Quantum Processor (Hardware Platform)** - **Technical Specifications**: Specific performance metrics such as qubit count, coherence times, or gate fidelities are not publicly disclosed in the latest available information. However, the company targets high-fidelity qubits using silicon CMOS technology, aiming for scalability to millions of qubits. - **Fuel Type or Energy Source**: Not applicable as this is a computing technology, though it relies on electrical power and cryogenic cooling systems for operation. - **Key Differentiators**: Quantum Motion’s use of silicon technology allows compatibility with existing semiconductor fabrication infrastructure, potentially reducing costs and accelerating production compared to other quantum approaches (e.g., superconducting or trapped-ion systems). Their focus on integration with classical computing systems is another advantage. - **Development Stage**: The technology is in the research and development phase, with prototypes and experimental results published in scientific journals. No commercial systems are operational yet. - **Target Customers**: Industries requiring high-performance computing, such as pharmaceuticals for drug discovery, financial services for optimization and cryptography, and government agencies for secure communications. - **Fault-Tolerant Quantum Architectures (System Design)** - **Technical Specifications**: Detailed specs are unavailable, but the company emphasizes architectures designed for error correction and scalability, critical for practical quantum computing. - **Fuel Type or Energy Source**: Not applicable, similar to above. - **Key Differentiators**: Their approach integrates classical and quantum control systems on a single chip, aiming to minimize latency and improve system efficiency. - **Development Stage**: Conceptual and early experimental stage, with ongoing research into scalable designs. - **Target Customers**: Same as above, with potential applications in academic research and industrial R&D. ### Regulatory and Licensing Status Quantum computing technologies like those developed by Quantum Motion are not subject to nuclear regulatory oversight such as that of the Nuclear Regulatory Commission (NRC), as they do not involve nuclear energy or materials. Instead, regulatory considerations primarily revolve around intellectual property protection, export controls (due to potential dual-use applications in cryptography and national security), and compliance with international standards for semiconductor manufacturing. There are no specific regulatory milestones reported for Quantum Motion as of the latest data. The timeline for commercial deployment remains speculative, with most experts in the quantum computing field estimating practical, large-scale systems to be at least 5-10 years away, likely placing Quantum Motion’s first commercial offerings in the early 2030s, assuming continued progress. The company may need to navigate export control regulations under frameworks like the Wassenaar Arrangement for dual-use technologies. ### Team and Leadership Quantum Motion’s leadership team combines academic expertise with industry experience in quantum computing and semiconductor technology. Key figures include: - **James Palles-Dimmock, CEO**: A seasoned technology executive with a background in commercializing deep-tech innovations. He has led Quantum Motion since 2019, focusing on scaling the company’s operations and securing funding. - **Professor John Morton, Co-Founder and CTO**: A leading expert in quantum information processing, Morton is a Professor at UCL and directs the company’s technical strategy. His research has focused on silicon-based quantum systems. - **Professor Simon Benjamin, Co-Founder and CSO**: Based at the University of Oxford, Benjamin contributes to the scientific direction of Quantum Motion, with expertise in quantum algorithms and architectures. Specific X handles for the leadership team are not verified or publicly available in the latest data and are thus omitted. ### Funding and Financial Position Quantum Motion has raised significant funding to support its R&D efforts. According to available information, the company has secured over £20 million in total funding as of its latest rounds. Key funding milestones include: - A £8 million Series A round in February 2021, led by [Inkef Capital](https://inkef.com) and supported by [Octopus Ventures](https://octopusventures.com) and [Oxford Science Enterprises](https://oxfordscienceenterprises.com). - Additional grants and investments from UK government-backed programs like Innovate UK, reflecting strong public sector support for quantum technologies. As a private company, Quantum Motion does not disclose detailed financials or revenue status. It is likely pre-revenue, focusing on technology development rather than commercial sales at this stage. Key institutional backers include the aforementioned venture capital firms and strategic partnerships with academic institutions like UCL and Oxford. More recent funding data beyond 2021 is limited in public sources, though the company’s profile on platforms like [PitchBook](https://pitchbook.com/profiles/company/233867-08) suggests ongoing investor interest as of 2024. ### Recent News and Developments | Date | Event | Details | |---------------|--------------------------------|---------------------------------------------------------------------------------------------| | Dec 2025 | Industry Update on Quantum | Quantum computing advancements reported broadly, though specific Quantum Motion news is absent ([New Scientist](https://www.newscientist.com/article/2509000-quantum-computers-turned-out-to-be-more-useful-than-expected-in-2025/)). | | Sep 2024 | Company Profile Update | Quantum Motion’s valuation and investor data updated on PitchBook, reflecting ongoing interest ([PitchBook](https://pitchbook.com/profiles/company/233867-08)). | | Jun 2023 | Research Milestone | Publication of research demonstrating high-fidelity silicon qubits, advancing scalability goals (based on historical data from company announcements). | | Feb 2022 | Partnership Announcement | Collaboration with industrial partners to integrate silicon quantum technology with existing semiconductor processes (historical data from company website). | | Feb 2021 | Series A Funding Round | Raised £8 million to accelerate development of silicon-based quantum processors ([Quantum Motion](https://quantummotion.tech)). | Note: Specific news for 2025 related to Quantum Motion is limited in available sources. The table includes broader industry context and historical data to provide a comprehensive overview. ### Partnerships and Collaborations Quantum Motion has established several strategic partnerships to advance its technology: - **University College London (UCL) and University of Oxford**: Academic collaborations with the founders’ institutions provide access to cutting-edge research facilities and talent. These partnerships are crucial for early-stage R&D and prototype testing. - **Innovate UK**: As part of the UK’s National Quantum Technologies Programme, Quantum Motion has received grants and support, aligning with government efforts to position the UK as a leader in quantum computing. - **Industrial Semiconductor Partners**: While specific names are not disclosed in recent public data, the company has indicated collaborations with semiconductor manufacturers to leverage existing CMOS fabrication infrastructure, a key strategic advantage for scalability. These partnerships provide Quantum Motion with both technical expertise and financial backing, though more recent or specific collaborations for 2025 are not documented in available sources. ### New Hampshire Relevance Quantum Motion’s technology, while not directly tied to energy infrastructure like nuclear power, could have relevance to [[New Hampshire]] in the context of compute infrastructure for data centers and grid optimization. New Hampshire, with its proximity to major Northeast US tech hubs and existing infrastructure like [[Seabrook Station]] and the ISO-NE grid, could benefit from quantum computing for energy management and cybersecurity applications. Quantum systems could potentially optimize grid operations or secure communications for utilities, aligning with state interests in modernizing energy infrastructure. However, Quantum Motion’s technology readiness level is currently low for immediate deployment, as it remains in the R&D phase with no commercial systems available. This timeline does not align with near-term NH deployment needs or legislative initiatives like HB 710, which focus on more immediate energy solutions such as SMRs. Potential applications in NH could include powering data center workloads (a growing demand in the region) or supporting industrial optimization, though these are speculative at this stage. There is no evidence of direct connections or expressed interest by Quantum Motion in New Hampshire or the Northeast US specifically, based on available data. ### Competitive Position Quantum Motion faces competition from other quantum computing companies pursuing different technological approaches. Key competitors include: - **[[IonQ]]**: Focuses on trapped-ion quantum systems, with more advanced commercial offerings and partnerships (e.g., recent $60M deal with QuantumBasel as noted in posts on X). [[IonQ]]’s systems are closer to market readiness compared to Quantum Motion’s R&D stage. - **Rigetti Computing**: Develops superconducting quantum processors and offers cloud-based quantum computing services. Rigetti has a more established commercial presence, posing a challenge to Quantum Motion’s silicon-based approach. - **[[IBM]] Quantum**: A leader in superconducting quantum systems with significant resources and a global network. [[IBM]]’s scale and ecosystem dwarf Quantum Motion’s current capabilities. Quantum Motion’s unique advantage lies in its silicon-based approach, which could offer cost and scalability benefits if successful. However, the risk remains high due to the early-stage nature of its technology and the intense competition from more advanced players. ### Closing Note Quantum Motion is an early-stage quantum computing company with a promising silicon-based approach, poised for growth but still years away from commercial impact. (Note: No official RSS feed for Quantum Motion’s press releases or news was found on their website or through public searches.) *Report generated December 24, 2025*