Quantum computing is scalable on a planar array of qubits with fabrication defects
Abstract
To successfully execute large-scale algorithms, a quantum computer will need to perform its elementary operations near perfectly. This is a fundamental challenge since all physical qubits suffer a considerable level of noise. Moreover, real systems are likely to have a finite yield, i.e. some non-zero proportion of the components in a complex device may be irredeemably broken at the fabrication stage. We present a threshold theorem showing that an arbitrarily large quantum computation can be completed with a vanishing probability of failure using a two-dimensional array of noisy qubits with a finite density of fabrication defects. To complete our proof we introduce a robust protocol to measure high-weight stabilizers to compensate for large regions of inactive qubits. We obtain our result using a surface code architecture. Our approach is therefore readily compatible with ongoing experimental efforts to build a large-scale quantum computer.
Cite
@article{arxiv.2111.06432,
title = {Quantum computing is scalable on a planar array of qubits with fabrication defects},
author = {Armands Strikis and Simon C. Benjamin and Benjamin J. Brown},
journal= {arXiv preprint arXiv:2111.06432},
year = {2023}
}
Comments
18 pages, 8 figures; this version contains a more generalised proof of the main results