About The Role and Team
Since 2021 our team has been listed every year in the “Top 100 Startups worth watching” in the EE Times in 2021 and 2022, and our technology breakthroughs have been featured in The Telegraph, BBC and the New Statesman. Our founders are internationally renowned researchers from UCL and Oxford University who have pioneered the development of qubits and quantum computing architectures. Our chairman is the co-founder of Cadence and Synopsys, the two leading companies in the area of Electronic Design Automation. We’re backed by a team of top-tier investors, and we have recently closed our Series C funding of $160 million.
Our Team
We bring together the brightest quantum engineers, integrated circuit (IC) engineers, quantum computing theoreticians and software engineers to create a unique, world-leading team, working together closely to maximise our combined expertise. Our collaborative and interdisciplinary culture is an ideal fit for anyone who thrives in a cutting-edge research and development environment focused on tackling big challenges and contributing to the development of scalable quantum computers based on silicon technology.
Our team of 100+ is based across London, Oxford, San Sebastián and Sydney, with our primary hub in Islington (London).
Functions of the Role
Open Application – Quantum Motion
At Quantum Motion, we are always keen to connect with talented individuals who are excited by the potential of quantum computing, even if there isn’t a current vacancy that aligns with your background.
We are building a world-class team of scientists, engineers, and professionals working at the forefront of scalable quantum technology. Whether your expertise lies in quantum physics, engineering, software, product, operations or other areas - we welcome expressions of interest from individuals who are motivated by complex challenges and meaningful innovation.
Why submit an open application?
If you don’t see a suitable role advertised today, sharing your details allows us to consider you for future opportunities as our team continues to grow. We regularly review open applications when new positions become available and will be in touch if there is a suitable vacancy.
What we look for:
- A strong interest in quantum technologies and our mission
- Relevant experience in your field of expertise
- Curiosity, collaboration, and a problem-solving mindset
How to apply:
Please submit your CV along with a brief note outlining your areas of interest and the type of role you would like to be considered for.
While we may not be able to respond to every application immediately, we genuinely value your interest in Quantum Motion and will be in touch should a suitable opportunity arise.
Join us as we shape the future of quantum computing.
Experience - Essentials
At Quantum Motion, we look for technically exceptional people who are motivated by solving genuinely hard problems at the frontier of science and engineering.
Because quantum computing sits at the intersection of multiple disciplines, we value candidates who combine strong technical fundamentals with curiosity, adaptability and a collaborative mindset. Depending on the role, that might mean deep expertise in physics, semiconductor engineering, cryogenics, software, hardware systems, control engineering, algorithms, scalable infrastructure, as well as commercial, product, marketing, operations or finance disciplines that help translate deep technology into a scalable global business.
Experience - Desirable
We look for people who can think rigorously, work through ambiguity and contribute in fast-moving, highly interdisciplinary environments. Technical excellence matters, but so does the ability to communicate clearly, learn quickly and work effectively across teams.
Most importantly, we look for people excited by the challenge of building scalable quantum computers capable of operating in standard data centres, and who want to help turn ambitious research into real-world technology.
Benefits
● Be part of a creative, world-leading team
● Competitive salary and share options scheme
● Choose your own laptop/kit
● Flexible working
EEO Statement
Quantum Motion is an equal opportunity employer. All qualified applicants will receive consideration for employment without regard to age, disability, gender reassignment, marital or civil partner status, pregnancy and maternity, race, colour, nationality, ethnic or national origin, religion or belief, sex, sexual orientation, or any other characteristic protected by applicable local laws (including the UK Equality Act 2010 and Spanish Employment Law).
TECHNICAL & MARKET ANALYSIS | Appended by Quantum.Jobs
The structural advancement of the quantum ecosystem increasingly depends on highly interdisciplinary pipelines that bridge the gap between theoretical physics and industrial-grade engineering. Open application frameworks serve as a critical strategic mechanism for capturing specialized talent in a market defined by extreme scarcity and rapid Technology Readiness Level (TRL) progression. Within the quantum value chain, these roles represent the foundational human capital necessary for the transition from laboratory prototypes to scalable, fault-tolerant architectures. Market signals from international quantum strategies indicate that workforce development is now the primary determinant of operational scaling for firms focusing on silicon-based qubit technologies. By enabling continuous talent acquisition outside of rigid vacancy cycles, these pathways ensure the long-term viability of deep-tech ventures by maintaining a high-density pool of expertise across hardware, software, and commercial operations.
The global quantum landscape is currently navigating a pivot from scientific discovery to systems integration, where the ability to coordinate diverse technical domains is a core competitive advantage. For companies specializing in silicon-based architectures, the integration of CMOS-compatible processes with quantum operations is a significant macro constraint, requiring a workforce that understands both semiconductor manufacturing and quantum coherence. Ecosystem analysis suggests that the talent bottleneck is no longer restricted to PhD-level physicists but has expanded to include systems engineers, cryogenics experts, and compiler developers who can operate within high-fidelity constraints.
Macro-level investment patterns, including the rise in Series C funding rounds across the sector, highlight the shift toward commercial-scale manufacturing and infrastructure readiness. As firms move into the pilot production phase, the dependency on a stable supply chain of multidisciplinary expertise becomes acute. The fragmentation of the vendor ecosystem further complicates this, as specialized components for dilution refrigerators and microwave control electronics require custom internal development or deep technical partnership.
Furthermore, the emergence of hybrid classical-quantum workflows demands a workforce capable of managing the interface between traditional high-performance computing (HPC) and quantum processing units (QPUs). This architectural coupling is essential for achieving practical quantum advantage in domains such as materials simulation and cryptographic benchmarking. Ongoing ecosystem initiatives aim to accelerate readiness for practical quantum applications by fostering these interdisciplinary connections, ensuring that the transition to utility-scale computing is supported by a robust, adaptable labor force capable of navigating the inherent ambiguity of a nascent industry.
The capability architecture for this sector-level role type centers on the integration of fundamental physics with scalable engineering frameworks. At the hardware layer, expertise in semiconductor device physics, cryogenics, and microwave engineering is essential for the stabilization of qubit environments and the reduction of environmental decoherence. This is coupled with a software interface layer involving quantum circuit optimization, error mitigation strategies, and the development of hardware-agnostic control stacks. These capabilities are critical for ensuring the structural throughput of hardware development, as they directly influence the fidelity and connectivity of quantum processors.
Beyond pure technical functions, the role type facilitates a cross-functional coupling between research and commercialization, requiring proficiency in translating abstract scientific breakthroughs into patentable IP and viable product roadmaps. The ability to work across different layers of the quantum stack—from the physical qubit to the algorithmic output—allows for a more cohesive approach to system design, reducing the iteration friction typical of siloed development environments. By maintaining these broad technical interfaces, the workforce enables a level of operational agility that is prerequisite for navigating the shift toward fault-tolerant computing and the integration of quantum systems into standard data centers.
Accelerates the deterministic progression of technology readiness levels across the quantum hardware stack
Mitigates systemic risks associated with the global shortage of specialized quantum engineering talent
Facilitates the translation of academic research into standardized industrial-grade quantum architectures
Strengthens the reliability of silicon-based quantum processing units through improved CMOS integration
Reduces the integration friction between quantum hardware and classical high-performance computing environments
Supports the scaling of quantum manufacturing by stabilizing high-purity production and testing workflows
Optimizes the lifecycle of capital-intensive laboratory assets including dilution refrigerators and cleanroom utilities
Enhances the reproducibility of quantum benchmarking results through standardized control and readout protocols
Shortens the iteration cycles for new qubit designs by maintaining a multidisciplinary technical interface
Protects strategic investments in deep-tech by ensuring the continuous influx of high-density technical expertise
Promotes the development of a resilient talent pipeline capable of navigating sector-wide infrastructure dependencies
Drives the transition toward fault-tolerant quantum systems through the application of advanced error correction codes
Industry Tags: Quantum Computing, Silicon Qubits, Deep Tech Engineering, CMOS Integration, Quantum Information Science, Semiconductor Manufacturing, Systems Engineering, Cryogenic Systems, Scalable Hardware
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