Boundaries of Acceptable Defectiveness: Redefining Surface Code Robustness under Heterogeneous Noise

• URL: http://arxiv.org/abs/2510.22001v1
• Date: Fri, 24 Oct 2025 20:09:06 GMT
• Title: Boundaries of Acceptable Defectiveness: Redefining Surface Code Robustness under Heterogeneous Noise
• Authors: Jacob S. Palmer, Kaitlin N. Smith,
• Abstract summary: A variety of past research on superconducting qubits shows that these devices exhibit considerable variation.<n>Our work aims to define the boundaries of acceptable defectiveness.<n>We find that substantial qubit variation around a seemingly acceptable physical error rate can severely degrade logical qubit performance.
• Score: 1.9962959874305284
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: A variety of past research on superconducting qubits shows that these devices exhibit considerable variation and thus cannot be accurately depicted by a uniform noise model. To combat this often unrealistic picture of homogeneous noise in quantum processors during runtime, our work aims to define the boundaries of acceptable defectiveness (BADs), or the upper boundary of a qubits physical error, past which this defective qubit entirely degrades the logical computation and should be considered faulty and removed from the surface code mapping. Using the QEC simulation package STIM, repetition code circuits on rotated surface codes were generated, sampled, and analyzed from distances 3 to 17, with various defective error rates and outlier defect locations. In addition, we simulated heterogeneous noise models using the same parameters to test how increasingly deviated distributions of physical errors scale across code distances under realistic, heterogeneous noise models that are informed by current superconducting hardware. The results suggest that there are, in fact, boundaries of acceptable defectiveness in which a defective qubit, with a physical error rate $<= .75$\%, can be left in the lattice with negligible impact on logical error rate given sufficient code distances and proper placement in the lattice. On the other hand, we find that substantial qubit variation around a seemingly acceptable physical error rate can severely degrade logical qubit performance. As a result, we propose that defectiveness of both individual qubits and the overall uniformity of lattice fidelity should not be viewed as all or nothing, but instead as a spectrum. Our research demonstrates how heterogeneity directly impacts logical error rate and provides preliminary goals and metrics for hardware designers to meet in order to achieve target logical performance with imperfect, non-uniform qubit qualities.

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