Characterizing scalable measures of quantum resources
Abstract
The question of how quantities, like entanglement and coherence, depend on the number of copies of a given state is addressed. This is a hard problem, often involving optimizations over Hilbert spaces of large dimensions. Here, we propose a way to circumvent the direct evaluation of such quantities, provided that the employed measures satisfy a self-similarity property. We say that a quantity is {\it scalable} if it can be described as a function of the variables for , while, preserving the tensor-product structure. If analyticity is assumed, recursive relations can be derived for the Maclaurin series of , which enable us to determine its possible functional forms (in terms of the mentioned variables). In particular, we find that if depends only on , , and , then it is completely determined by Fibonacci polynomials, to leading order. We show that the one-shot distillable (OSD) entanglement is well described as a scalable measure for several families of states. For a particular two-qutrit state , we determine the OSD entanglement for from smaller tensorings, with an accuracy of and no extra computational effort. Finally, we show that superactivation of non-additivity may occur in this context.
Cite
@article{arxiv.1910.10285,
title = {Characterizing scalable measures of quantum resources},
author = {Fernando Parisio},
journal= {arXiv preprint arXiv:1910.10285},
year = {2020}
}
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