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Temporal-mode continuous-variable 3-dimensional cluster state for topologically-protected measurement-based quantum computation

Quantum Physics 2020-09-11 v2

Abstract

Measurement-based quantum computation with continuous variables in an optical setup shows the great promise towards implementation of large-scale quantum computation, where the time-domain multiplexing approach enables us to generate the large-scale cluster state used to perform measurement-based quantum computation. To make effective use of the advantage of the time-domain multiplexing approach, in this paper, we propose the method to generate the large-scale 3-dimensional cluster state which is a platform for topologically protected measurement-based quantum computation. Our method combines a time-domain multiplexing approach with a divide-and-conquer approach, and has the two advantages for implementing large-scale quantum computation. First, the squeezing level for verification of the entanglement of the 3-dimensional cluster states is experimentally feasible. The second advantage is the robustness against analog errors derived from the finite squeezing of continuous variables during topologically-protected measurement-based quantum computation. Therefore, our method is a promising approach to implement large-scale quantum computation with continuous variables.

Keywords

Cite

@article{arxiv.2004.05750,
  title  = {Temporal-mode continuous-variable 3-dimensional cluster state for topologically-protected measurement-based quantum computation},
  author = {Kosuke Fukui and Warit Asavanant and Akira Furusawa},
  journal= {arXiv preprint arXiv:2004.05750},
  year   = {2020}
}

Comments

14 pages, 5 figures

R2 v1 2026-06-23T14:48:52.313Z