English

Correlated Error Bursts in a Gap-Engineered Superconducting Qubit Array

Quantum Physics 2025-06-24 v1 Mesoscale and Nanoscale Physics

Abstract

One of the roadblocks towards the implementation of a fault-tolerant superconducting quantum processor is impacts of ionizing radiation with the qubit substrate. Such impacts temporarily elevate the density of quasiparticles (QPs) across the device, leading to correlated qubit error bursts. The most damaging errors, T1T_1 errors, stem from QP tunneling across the qubit Josephson junctions (JJs). Recently, we demonstrated that this type of error can be strongly suppressed by engineering the profile of superconducting gap at the JJs in a way that prevents QP tunneling. In this work, we identify a new type of impact-induced correlated error that persists in the presence of gap engineering. We observe that impacts shift the frequencies of the affected qubits, and thus lead to correlated phase errors. The frequency shifts are systematically negative, reach values up to 3MHz3\,{\rm MHz}, and last for 1ms\sim 1\,{\rm ms}. We provide evidence that the shifts originate from QP-qubit interactions in the JJ region. Further, we demonstrate that the shift-induced phase errors can be detrimental to the performance of quantum error correction protocols.

Keywords

Cite

@article{arxiv.2506.18228,
  title  = {Correlated Error Bursts in a Gap-Engineered Superconducting Qubit Array},
  author = {Vladislav D. Kurilovich and Gabrielle Roberts and Leigh S. Martin and Matt McEwen and Alec Eickbusch and Lara Faoro and Lev B. Ioffe and Juan Atalaya and Alexander Bilmes and John Mark Kreikebaum and Andreas Bengtsson and Paul Klimov and Matthew Neeley and Wojciech Mruczkiewicz and Kevin Miao and Igor L. Aleiner and Julian Kelly and Yu Chen and Kevin Satzinger and Alex Opremcak},
  journal= {arXiv preprint arXiv:2506.18228},
  year   = {2025}
}
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