English

Entanglement thresholds for random induced states

Quantum Physics 2015-05-12 v3 Functional Analysis Probability

Abstract

For a random quantum state on H=CdCdH=C^d \otimes C^d obtained by partial tracing a random pure state on HCsH \otimes C^s, we consider the whether it is typically separable or typically entangled. For this problem, we show the existence of a sharp threshold s0=s0(d)s_0=s_0(d) of order roughly d3d^3. More precisely, for any a>0a > 0 and for d large enough, such a random state is entangled with very large probability when s<(1a)s0s < (1-a)s_0, and separable with very large probability when s>(1+a)s0s > (1+a)s_0. One consequence of this result is as follows: for a system of N identical particles in a random pure state, there is a threshold k0=k0(N)N/5k_0 = k_0(N) \sim N/5 such that two subsystems of k particles each typically share entanglement if k>k0k > k_0, and typically do not share entanglement if k<k0k < k_0. Our methods work also for multipartite systems and for "unbalanced" systems such as CdCdC^{d} \otimes C^{d'}, ddd \neq d'. The arguments rely on random matrices, classical convexity, high-dimensional probability and geometry of Banach spaces; some of the auxiliary results may be of reference value. A high-level non-technical overview of the results of this paper and of a related article arXiv:1011.0275 can be found in arXiv:1112.4582.

Keywords

Cite

@article{arxiv.1106.2264,
  title  = {Entanglement thresholds for random induced states},
  author = {Guillaume Aubrun and Stanislaw J. Szarek and Deping Ye},
  journal= {arXiv preprint arXiv:1106.2264},
  year   = {2015}
}

Comments

34 pages; v.3: reorganized proof, new results only in section 7.1, references added; v.2: main result strengthened (much stronger threshold property) allowing the sharp "N-particle" interpretation of the results stated in the abstract, new appendix on majorization and \infty-Wasserstein distance, references added

R2 v1 2026-06-21T18:21:00.161Z