Lead Electronics Engineer

Lead Electronics Engineer

The future is quantum. Oxford Ionics is at the forefront of pioneering quantum computing, delivering world-leading innovation to create the most powerful, accurate, and reliable quantum systems. Quantum computing offers a radically new way of building computers that harnesses the power of quantum physics to outperform conventional supercomputers exponentially. Using our unique trapped-ion technology, we are leading the race to unleash quantum computing's unparalleled potential.

What to expect

We're looking for a Lead Electronics Engineer to become the founding member of our new Electronics Engineering function, a chance to shape both the technology and the team that will power the world's most advanced quantum computers.

In this role, you'll take ownership of mixed-signal PCB development for our quantum systems, from low-noise analogue paths to high-speed digital subsystems (FPGAs, DACs, DDS). You'll also establish the processes, standards and tools that will define the Electronics function, helping to grow the team in Oxford and collaborating closely across hardware and software.

Our quantum core is based on trapped-ion qubits, controlled by devices fabricated by a tier-one semiconductor partner. We manipulate the ions using precision electrical signals and laser light driven by real-time FPGA systems. Quantum states are read out by CMOS sensors and tuned lasers, with the entire system orchestrated by Xilinx FPGAs and SoCs.

This is a lab-centred role that blends hands-on technical delivery with technical leadership. You'll be the engineer optimising today's lab-grade systems and the architect driving tomorrow's production-grade, data-centre-class electronics.

What you'll be responsible for

You'll own the design, validation and delivery of the electronic systems that power our quantum computers and establish the foundation of the Electronics Engineering function.

1. Lead the end-to-end PCB and electronic module development – requirements capture, schematic design, simulation, bring-up, verification and production release.
2. Design and optimise low-noise analogue, RF (up to 1 GHz), power-distribution and mixed-signal circuits, collaborating with FPGA and software teams for seamless system integration.
3. Build and maintain component libraries, BoMs, design rules and documentation, setting best-practice standards for the function.
4. Own supplier and manufacturing partnerships, agree design rules and stack-ups, resolve build queries, and sign off first-article inspections.
5. Develop automated test fixtures and calibration routines, improving first-pass yield and supporting EMC, safety and compliance requirements.
6. Oversee system validation in the lab, addressing earth-leakage, ground loops and integration challenges in complex multi-rack systems.
7. As the founding member of the team, recruit and mentor engineers, lead design reviews, and set the technical direction to build a scalable, high-performing function.