Irreducible magic sets for $n$-qubit systems
Abstract
Magic sets of observables are minimal structures that capture quantum state-independent advantage for systems of qubits and are, therefore, fundamental tools for investigating the interface between classical and quantum physics. A theorem by Arkhipov (arXiv:1209.3819) states that -qubit magic sets in which each observable is in exactly two subsets of compatible observables can be reduced either to the two-qubit magic square or the three-qubit magic pentagram [N. D. Mermin, Phys. Rev. Lett. 65, 3373 (1990)]. An open question is whether there are magic sets that cannot be reduced to the square or the pentagram. If they exist, a second key question is whether they require qubits, since, if this is the case, these magic sets would capture minimal state independent quantum advantage that is specific for -qubit systems with specific values of . Here, we answer both questions affirmatively. We identify magic sets which cannot be reduced to the square or the pentagram and require , or qubits. In addition, we prove a generalized version of Arkhipov's theorem providing an efficient algorithm for, given a hypergraph, deciding whether or not it can accommodate a magic set, and solve another open problem, namely, given a magic set, obtaining the tight bound of its associated noncontextuality inequality.
Cite
@article{arxiv.2202.13141,
title = {Irreducible magic sets for $n$-qubit systems},
author = {Stefan Trandafir and Petr Lisoněk and Adán Cabello},
journal= {arXiv preprint arXiv:2202.13141},
year = {2022}
}
Comments
5+13 pages, 3+1 figures