Highly noise resistant multiqubit quantum correlations

Laskowski, W. and Vértesi, Tamás and Wies̈niak, M. (2015) Highly noise resistant multiqubit quantum correlations. JOURNAL OF PHYSICS A-MATHEMATICAL AND THEORETICAL, 48 (46). ISSN 1751-8113

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Abstract

We analyze robustness of correlations of the N -qubit GHZ and Dicke states against white noise admixture. For sufficiently large N , the Dicke states (for any number of excitations) lead to more robust violation of local realism than the GHZ states (e.g. for N > 8 for the W state). We also identify states that are the most resistant to white noise. Surprisingly, it turns out that these states are the GHZ states augmented with fully product states. Based on our numerical analysis conducted up to N = 8, and an analytical formula derived for any N parties, we conjecture that the three-qubit GHZ state augmented with a product of (N − 3) pure qubits is the most robust against white noise admixture among any N -qubit state. As a by-product, we derive a single Bell inequality and show that it is violated by all pure entangled states of a given number of parties. This gives an alternative proof of Gisin’s theorem.

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