English

Annihilating Entanglement Between Cones

Quantum Physics 2023-01-18 v2 Functional Analysis

Abstract

Every multipartite entangled quantum state becomes fully separable after an entanglement breaking quantum channel acted locally on each of its subsystems. Whether there are other quantum channels with this property has been an open problem with important implications for entanglement theory (e.g., for the distillation problem and the PPT squared conjecture). We cast this problem in the general setting of proper convex cones in finite-dimensional vector spaces. The entanglement annihilating maps transform the kk-fold maximal tensor product of a cone C1C_1 into the kk-fold minimal tensor product of a cone C2C_2, and the pair (C1,C2)(C_1,C_2) is called resilient if all entanglement annihilating maps are entanglement breaking. Our main result is that (C1,C2)(C_1,C_2) is resilient if either C1C_1 or C2C_2 is a Lorentz cone. Our proof exploits the symmetries of the Lorentz cones and applies two constructions resembling protocols for entanglement distillation: As a warm-up, we use the multiplication tensors of real composition algebras to construct a finite family of generalized distillation protocols for Lorentz cones, containing the distillation protocol for entangled qubit states by Bennett et al. as a special case. Then, we construct an infinite family of protocols using solutions to the Hurwitz matrix equations. After proving these results, we focus on maps between cones of positive semidefinite matrices, where we derive necessary conditions for entanglement annihilation similar to the reduction criterion in entanglement distillation. Finally, we apply results from the theory of Banach space tensor norms to show that the Lorentz cones are the only cones with a symmetric base for which a certain stronger version of the resilience property is satisfied.

Keywords

Cite

@article{arxiv.2110.11825,
  title  = {Annihilating Entanglement Between Cones},
  author = {Guillaume Aubrun and Alexander Müller-Hermes},
  journal= {arXiv preprint arXiv:2110.11825},
  year   = {2023}
}

Comments

39 pages, no figures, extended results in appendix

R2 v1 2026-06-24T07:06:29.529Z