English

Almost all graphs are vertex-minor universal

Quantum Physics 2026-02-24 v2 Combinatorics

Abstract

Answering a question of Claudet, we prove that the uniformly random graph GG(n,1/2)G\sim \mathbb G(n, 1/2) is Ω(n)\Omega(\sqrt n)-vertex-minor universal with high probability. That is, for some constant α0.911\alpha\approx 0.911, any graph on any αn\alpha\sqrt n specified vertices of GG can be obtained as a vertex-minor of GG. This has direct implications for quantum communications networks: an nn-vertex kk-vertex-minor universal graph corresponds to an nn-qubit kk-stabilizer universal graph state, which has the property that one can induce any stabilizer state on any kk qubits using only local operations and classical communications. We further employ our methods in two other contexts. We obtain a bipartite pivot-minor version of our main result, and we use it to derive a universality statement for minors in random binary matroids. We also introduce the vertex-minor Ramsey number Rvm(k)R_{\mathrm{vm}}(k) to be the smallest value nn such that every nn-vertex graph contains an independent set of size kk as a vertex-minor. Supported by our main result, we conjecture that Rvm(k)R_{\mathrm{vm}}(k) is polynomial in kk. We prove Ω(k2)Rvm(k)2k1\Omega(k^2) \leq R_{\mathrm{vm}}(k) \leq 2^k - 1.

Keywords

Cite

@article{arxiv.2602.09049,
  title  = {Almost all graphs are vertex-minor universal},
  author = {Ruben Ascoli and Bryce Frederickson and Sarah Frederickson and Caleb McFarland and Logan Post},
  journal= {arXiv preprint arXiv:2602.09049},
  year   = {2026}
}

Comments

33 pages

R2 v1 2026-07-01T10:28:35.027Z