Related papers: Violation of Svetlichny's inequality in a system of spins $j$

Violation of Svetlichny's inequality in a system of spins $j$

URL: http://arxiv.org/abs/2505.01014v1
Date: Fri, 02 May 2025 05:26:08 GMT
Title: Violation of Svetlichny's inequality in a system of spins $j$
Authors: Yang Xiang, Yuan Tao,
Abstract summary: We present a unified scheme that enables the violation of Svetlichny's inequality (SI) in arbitrary non-zero spin particle systems.<n>We also prove that the upper bound of Svetlichny's operator within the framework of local hidden variable theory is $sqrt2N+1$.
Score: 8.42055107013918
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum multi-particle correlations are one of the most intriguing properties of quantum entanglement, arising from collective entangled states of multiple particles. Svetlichny's inequality (SI) was the first method proposed to test the existence of such correlations. Previous studies have primarily focused on $1/2$-spin particle systems. In this paper, we present a unified scheme that enables the violation of SI in arbitrary non-zero spin particle systems. Specifically, for all fermion systems, our scheme achieves the maximal quantum violation of SI for any number of particles. For boson systems, when the particle spin $j\geq2$, our scheme consistently realizes the violation of SI for any number of particles. When the particle spin $j=1$, our scheme can yield SI violation for up to $7$ particles. Furthermore, as the particle spin $j$ approaches infinity, our scheme achieves the maximal quantum violation of SI. To obtain these results, we also prove that the upper bound of Svetlichny's operator within the framework of local hidden variable theory is $\sqrt{2^{N+1}}$. These findings not only enhance our understanding of quantum correlations across various particle systems but also provide valuable insights for the development of quantum communication protocols that utilize entanglement and non-locality in multi-particle configurations.

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