We are pioneering advancements in quantum computing by utilising trapped ion technology and our proprietary laser-free quantum control methods. Our research and development efforts build on our fully integrated quantum processors that can be fabricated within standard silicon foundries. This unique approach allows us to leverage the highest-performing qubit technology while ensuring scalability and manufacturability using existing semiconductor fabrication technology. We approach quantum computing with a focus on minimising errors, striving to achieve ultra-low gate errors at scale. Our immediate objective is to develop functional quantum computers within the NISQ regime, aiming to construct fault-tolerant machines that require minimal QEC overhead. Our recent breakthroughs include achieving 99.97% fidelity in two-qubit gates and 99.9992% fidelity in single-qubit operations without error correction, setting new industry standards for performance.
What to expect{{:}
}You will play a pivotal part in shaping the future of our quantum computing systems by bridging the gap between theoretical research and practical implementation of quantum error correction (QEC). You'll work on developing QEC codes, simulation tools, algorithmic resource estimates and architectural designs that will directly influence the design and performance of our next-generation trapped ion quantum systems.
What you'll be responsible for{{:
}}You will play a key role in developing and refining the QEC strategies for our cutting-edge trapped-ion quantum computing systems. Your work will involve theoretical research and practical applications. Your responsibilities would include{{
iences This role is ideal for a motivated scientist who is eager to shape the future of quantum error correction in a dynamic, collaborative envir
rementsYou'll need at least 3 years of experience in QEC research, gained in either an academic or industry setting. You should have deep expertise in QEC and a track record demonstrating your contributions to the field. Strong scientific computing skills and experience in developing and running simulations are essential, as is the ability to collaborate effectively with experimentalists, bridging theoretical insights with practical experimen
tation.Familiarity with atomic physics and experience with trapped-ion qubits or similar quantum platforms would be valuable. Additionally, having a background in collaborative software engineering projects, with the ability to contribute to code development and review, will be beneficial. Analytical skills for interpreting experimental data to refine QEC models and approaches are also highly des
enefitsOxford Ionics is leading the way in quantum technology, and we need skilled, innovative individuals like you. We offer a range of benefits, including opportunities to further your career with a world-class team, business stock options, uncapped annual leave, flexible working, private medical and dental insurance for you and your family, and much more. Join us and be part of the future of quantum com
puting.Oxford Ionics is committed to equal opportunity f
or all.Copyright © 2024