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 E( N) is scalable if it can be described as a function of the variables \ E( i1),…, E( iq); N\ for N>ij, while, preserving the tensor-product structure. If analyticity is assumed, recursive relations can be derived for the Maclaurin series of E( N), which enable us to determine its possible functional forms (in terms of the mentioned variables). In particular, we find that if E( 2n) depends only on E(), E( 2), and n, 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 96 from smaller tensorings, with an accuracy of 97 \% and no extra computational effort. Finally, we show that superactivation of non-additivity may occur in this context.