Contextuality and The Single-Qubit Stabilizer Formalism
Abstract
Contextuality is a fundamental non-classical property of quantum theory, which has recently been proven to be a key resource for achieving quantum speed-ups in some leading models of quantum computation. However, which of the forms of contextuality, and how much thereof, are required to obtain a speed-up in an arbitrary model of quantum computation remains unclear. In this paper, we show that the relation between contextuality and a compuational advantage is more complicated than previously thought. We achieve this by proving that generalized contextuality is present even within the simplest subset of quantum operations, the so-called single-qubit stabilizer theory, which offers no computational advantage and was previously believed to be completely non-contextual. However, the contextuality of the single-qubit stabilizer theory can be confined to transformations. Therefore our result also demonstrates that the commonly considered prepare-and-measure scenarios (which ignore transformations) do not fully capture the contextuality of quantum theory.
Cite
@article{arxiv.1802.06121,
title = {Contextuality and The Single-Qubit Stabilizer Formalism},
author = {Piers Lillystone and Joel J. Wallman and Joseph Emerson},
journal= {arXiv preprint arXiv:1802.06121},
year = {2019}
}
Comments
5 pages, 1 figure