In some quantum computing (QC) architectures, entanglement of an arbitrary number of qubits can be generated in a single operation. This property has many potential applications, and may specifically be useful for quantum error correction (QEC). Stabilizer measurements can then be implemented using a single multi-qubit gate instead of several two-qubit gates, thus reducing circuit depth. In this study, the toric code is used as a benchmark to compare the performance of two-qubit and five-qubit gates within parity-check circuits. We consider trapped ion qubits that are controlled via Raman transitions, where the primary source of error is assumed to be spontaneous photon scattering. We show that a five-qubit M{\o}lmer-S{\o}rensen gate offers an approximately 40% improvement over two-qubit gates in terms of the fault tolerance threshold. This result indicates an advantage of using multi-qubit gates in the context of QEC.
@article{arxiv.2111.04047,
title = {Comparing Two-Qubit and Multi-Qubit Gates within the Toric Code},
author = {David Schwerdt and Yotam Shapira and Tom Manovitz and Roee Ozeri},
journal= {arXiv preprint arXiv:2111.04047},
year = {2022}
}
Comments
9 pages, 6 figures; updated simulation for five-qubit model, figures 5 and 6