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Geometry of the set of quantum correlations

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arxiv 1710.05892 v3 pith:JYCCDFWW submitted 2017-10-16 quant-ph

Geometry of the set of quantum correlations

classification quant-ph
keywords quantumgeometrycorrelationsbellclassicalfeaturesinputsparties
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It is well known that correlations predicted by quantum mechanics cannot be explained by any classical (local-realistic) theory. The relative strength of quantum and classical correlations is usually studied in the context of Bell inequalities, but this tells us little about the geometry of the quantum set of correlations. In other words, we do not have good intuition about what the quantum set actually looks like. In this paper we study the geometry of the quantum set using standard tools from convex geometry. We find explicit examples of rather counter-intuitive features in the simplest non-trivial Bell scenario (two parties, two inputs and two outputs) and illustrate them using 2-dimensional slice plots. We also show that even more complex features appear in Bell scenarios with more inputs or more parties. Finally, we discuss the limitations that the geometry of the quantum set imposes on the task of self-testing.

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  1. All pure entangled states can lead to fully nonlocal correlations

    quant-ph 2026-04 unverdicted novelty 7.0

    Non-maximally entangled states exhibit full nonlocality under simple Schmidt coefficient conditions, and all pure entangled states can be activated to full nonlocality with multiple copies.