5 years ago

Realistic Area-Law Bound on Entanglement from Exponentially Decaying Correlations.

Jaeyoon Cho

A remarkable feature of typical ground states of strongly-correlated many-body systems is that the entanglement entropy is not an extensive quantity. In one dimension, there exists a proof that a finite correlation length sets a constant upper-bound on the entanglement entropy, called the area law. However, the known bound exists only in a hypothetical limit, rendering its physical relevance highly questionable. In this paper, we give a simple proof of the area law for entanglement entropy in one dimension under the condition of exponentially decaying correlations. Our proof dramatically reduces the previously known bound on the entanglement entropy, bringing it, for the first time, into a realistic regime. The proof is composed of several simple and straightforward steps based on elementary quantum information tools, which reveal how the internal structure of many-body states is restricted by exponentially decaying correlations. We argue that the functional dependence of the bound on the correlation length is close to optimal.

Publisher URL: http://arxiv.org/abs/1706.09379

DOI: arXiv:1706.09379v6

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