# Quantifying Bell: the Resource Theory of Nonclassicality of Common-Cause   Boxes

**Authors:** Elie Wolfe, David Schmid, Ana Bel\'en Sainz, Ravi Kunjwal, and Robert, W. Spekkens

arXiv: 1903.06311 · 2020-07-01

## TL;DR

This paper develops a resource-theoretic framework to quantify nonclassical correlations in Bell scenarios, introducing new monotones and algorithms to distinguish classical from nonclassical resources.

## Contribution

It defines a formal resource theory for common-cause boxes, introduces efficient algorithms for resource conversion, and reveals limitations of Bell inequality violations in quantifying nonclassicality.

## Key findings

- Set of free operations forms a polytope.
- Two new monotones with closed-form expressions.
- Bell inequality violations are insufficient to quantify nonclassicality.

## Abstract

We take a resource-theoretic approach to the problem of quantifying nonclassicality in Bell scenarios. The resources are conceptualized as probabilistic processes from the setting variables to the outcome variables having a particular causal structure, namely, one wherein the wings are only connected by a common cause. We term them "common-cause boxes". We define the distinction between classical and nonclassical resources in terms of whether or not a classical causal model can explain the correlations. One can then quantify the relative nonclassicality of resources by considering their interconvertibility relative to the set of operations that can be implemented using a classical common cause (which correspond to local operations and shared randomness). We prove that the set of free operations forms a polytope, which in turn allows us to derive an efficient algorithm for deciding whether one resource can be converted to another. We moreover define two distinct monotones with simple closed-form expressions in the two-party binary-setting binary-outcome scenario, and use these to reveal various properties of the pre-order of resources, including a lower bound on the cardinality of any complete set of monotones. In particular, we show that the information contained in the degrees of violation of facet-defining Bell inequalities is not sufficient for quantifying nonclassicality, even though it is sufficient for witnessing nonclassicality. Finally, we show that the continuous set of convexly extremal quantumly realizable correlations are all at the top of the pre-order of quantumly realizable correlations. In addition to providing new insights on Bell nonclassicality, our work also sets the stage for quantifying nonclassicality in more general causal networks.

## Full text

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## Figures

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## References

112 references — full list in the complete paper: https://tomesphere.com/paper/1903.06311/full.md

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Source: https://tomesphere.com/paper/1903.06311