Abstract

Device error rates on current quantum computers have improved enough to where demonstrations of error correction below break-even are now possible. Still, the circuits required for quantum error correction introduce significant overhead and sometimes inject more errors than they correct. In this work, we introduce adaptive syndrome extraction as a scheme to improve code performance and reduce the quantum error correction cycle time by measuring only the stabilizer generators that are likely to provide useful syndrome information. We provide a concrete example of the scheme through the [[4,2,2]] code concatenated with a hypergraph product code and a syndrome extraction cycle that uses quantum error detection to modify the syndrome extraction circuits in real time. Compared to non-concatenated codes and non-adaptive syndrome extraction, we find that the adaptive scheme achieves over an order of magnitude lower logical error rates while requiring fewer CNOT gates and physical qubits. Furthermore, we show how to achieve fault-tolerant universal logical computation with [[4,2,2]]-concatenated hypergraph product codes.

Personal information

Noah Berthusen recently graduated from the University of Maryland with a PhD in Computer Science. He worked with Daniel Gottesman on quantum error correction. He will soon be joining Quantinuum to continue working on quantum error correction.

Please join with the link:

https://teams.microsoft.com/l/meetup-join/19%3ac6d9f8f64efa41d589422cb74733097a%40thread.tacv2/1757287889482?context=%7b%22Tid%22%3a%221608350e-92d5-431a-8ea2-bd2f76141620%22%2c%22Oid%22%3a%226101efd5-5d2e-4ac0-9e4f-1fc08858505d%22%7d