English

Vertex-minor universal graphs for generating entangled quantum subsystems

Quantum Physics 2024-09-19 v3 Discrete Mathematics

Abstract

We study the notion of kk-stabilizer universal quantum state, that is, an nn-qubit quantum state, such that it is possible to induce any stabilizer state on any kk qubits, by using only local operations and classical communications. These states generalize the notion of kk-pairable states introduced by Bravyi et al., and can be studied from a combinatorial perspective using graph states and kk-vertex-minor universal graphs. First, we demonstrate the existence of kk-stabilizer universal graph states that are optimal in size with n=Θ(k2)n=\Theta(k^2) qubits. We also provide parameters for which a random graph state on Θ(k2)\Theta(k^2) qubits is kk-stabilizer universal with high probability. Our second contribution consists of two explicit constructions of kk-stabilizer universal graph states on n=O(k4)n = O(k^4) qubits. Both rely upon the incidence graph of the projective plane over a finite field Fq\mathbb{F}_q. This provides a major improvement over the previously known explicit construction of kk-pairable graph states with n=O(23k)n = O(2^{3k}), bringing forth a new and potentially powerful family of multipartite quantum resources.

Keywords

Cite

@article{arxiv.2402.06260,
  title  = {Vertex-minor universal graphs for generating entangled quantum subsystems},
  author = {Maxime Cautrès and Nathan Claudet and Mehdi Mhalla and Simon Perdrix and Valentin Savin and Stéphan Thomassé},
  journal= {arXiv preprint arXiv:2402.06260},
  year   = {2024}
}
R2 v1 2026-06-28T14:43:50.112Z