English

Surface-Code Thresholds and Qubit Footprints in Shuttling-Based Spin-Qubit Railways

Quantum Physics 2026-05-08 v1

Abstract

We present a fault-tolerant mapping of rotated surface codes onto a 2×N2\times N silicon spin-qubit railway architecture, utilizing electron shuttling to resolve the wiring fan-out bottleneck. Employing circuit-level noise modeling, we evaluate threshold performances across various noise biases. We demonstrate that shuttling check qubits instead of data qubits fundamentally improves system thresholds. Crucially, under a noise model biased towards dephasing for spin-qubit shuttling, the non-CSS XZZX surface code outperforms standard CSS variants. By tailoring the topological code to this specific inherent bias, we show that the Megaquop footprint is achievable with a distance 7 code requiring a p=103p = 10^{-3} physical error rate, highlighting a pathway for substantial hardware reductions in early fault-tolerant quantum processors.

Keywords

Cite

@article{arxiv.2605.05881,
  title  = {Surface-Code Thresholds and Qubit Footprints in Shuttling-Based Spin-Qubit Railways},
  author = {Arun John Moncy and Reza Dastbasteh and Josu Etxezarreta Martinez and Ryo Nagai and Pedro M. Crespo and Normann Mertig and Charles Smith and Ruben M. Otxoa},
  journal= {arXiv preprint arXiv:2605.05881},
  year   = {2026}
}

Comments

14 pages, 12 figures

R2 v1 2026-07-01T12:54:25.368Z