My research focuses on practical quantum error correction and fault-tolerant architectures. Originally from Latvia, I moved to the UK to study Physics at the University of Warwick, where I was first introduced to quantum computing. I completed my PhD at the University of Oxford under Simon Benjamin, working primarily on quantum error correction after a brief initial project on quantum error mitigation. I then held a postdoctoral position in Dan Browne's group at UCL before returning to Oxford to join Balint Koczor's group. Alongside my academic research, I also work part-time with Quantum Motion, designing fault-tolerant architectures for their quantum computing platform.
High-performance syndrome extraction circuits for quantum codes
We present a fast and effective framework for analysing and designing syndrome extraction circuits (SECs). Our approach is based on left-right circuits, a general design for SECs which maintain low depth by staggering X and Z checks without interleaving gates. Initially proposed for specific classes of codes, we generalise this construction to arbitrary CSS codes and optimise the circuit structure to achieve low qubit idling time, large effective distance, and reduced minimum-weight failure mechanisms. A key component of our framework is the formal notion of residual errors and their associated distance metrics, which form lightweight tools for capturing error propagation and quantifying the potential harm of circuit-level errors. Applying our automated framework to diverse classes of codes, we observe consistent improvements in logical performance of up to an order of magnitude compared to existing single-ancilla SEC designs.
We also use these tools to prove that no non-interleaving SEC can achieve circuit distance 12 for the gross code, and identify an explicit circuit that we conjecture achieves distance 11, exceeding previously known constructions.