English

Systematic error tolerant multiqubit holonomic entangling gates

Quantum Physics 2021-11-18 v4

Abstract

Quantum holonomic gates hold built-in resilience to local noises and provide a promising approach for implementing fault-tolerant quantum computation. We propose to realize high-fidelity holonomic (N+1)(N+1)-qubit controlled gates using Rydberg atoms confined in optical arrays or superconducting circuits. We identify the scheme, deduce the effective multi-body Hamiltonian, and determine the working condition of the multiqubit gate. Uniquely, the multiqubit gate is immune to systematic errors, i.e., laser parameter fluctuations and motional dephasing, as the NN control atoms largely remain in the much stable qubit space during the operation. We show that CNC_N-NOT gates can reach same level of fidelity at a given gate time for N5N\leq5 under a suitable choice of parameters, and the gate tolerance against errors in systematic parameters can be further enhanced through optimal pulse engineering. In case of Rydberg atoms, the proposed protocol is intrinsically different from typical schemes based on Rydberg blockade or antiblockade. Our study paves a new route to build robust multiqubit gates with Rydberg atoms trapped in optical arrays or with superconducting circuits. It contributes to current efforts in developing scalable quantum computation with trapped atoms and fabricable superconducting devices.

Keywords

Cite

@article{arxiv.2012.02935,
  title  = {Systematic error tolerant multiqubit holonomic entangling gates},
  author = {Jin-Lei Wu and Yan Wang and Jin-Xuan Han and Yongyuan Jiang and Jie Song and Yan Xia and Shi-Lei Su and Weibin Li},
  journal= {arXiv preprint arXiv:2012.02935},
  year   = {2021}
}

Comments

Accepted to publish in Physical Review Applied

R2 v1 2026-06-23T20:44:52.454Z