Reduction-induced the Variation of Partial Von Neumann Entropy
- URL: http://arxiv.org/abs/2412.17027v1
- Date: Sun, 22 Dec 2024 14:11:29 GMT
- Title: Reduction-induced the Variation of Partial Von Neumann Entropy
- Authors: Jing-Min Zhu,
- Abstract summary: We propose Reduction-induced the Variation of Partial Von Neumann Entropy (RIVPVNE) to quantify QE in bipartite mixed states.<n>The computational complexity associated with this method is minimal. Moreover, it has a wide range of applicability.<n>We employ this method to investigate the organization and structure of some well-known QEs.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Whether from theoretical research or from practical research and applications, bipartite mixed-state quantum entanglement (QE) and its measures hold significant theoretical and practical importance. Widely recognized measures such as Entanglement of Formation and Relative Entropy of Entanglement, involve quantifying the minimum QE and reflect the inherently complex nature of their computation. In contrast, Concurrence is applicable only to 2*2 quantum systems, while Negativity is limited to 2*2 and 2*3 quantum systems. In this context, we propose a novel method termed Reduction-induced the Variation of Partial Von Neumann Entropy (RIVPVNE) to quantify QE in bipartite mixed states. The computational complexity associated with this method is minimal. Moreover, it has a wide range of applicability. The intuitive and clear physical representation, combined with straightforward computation, facilitates the exploration of its specific potential applications. Subsequently, we employ this method to investigate the organization and structure of some well-known QEs, analyzing its characteristics through both its physical implication and mathematical structure in comparison to the existing measures for bipartite QE measures, such as Partial Von Neumann Entropy, Concurrence, Negativity, Entanglement of Formation and Relative Entropy of Entanglement.
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