Related papers: Bound entanglement in thermalized states and black hole radiation

Bound entanglement in thermalized states and black hole radiation

URL: http://arxiv.org/abs/2110.02959v1
Date: Wed, 6 Oct 2021 18:00:00 GMT
Title: Bound entanglement in thermalized states and black hole radiation
Authors: Shreya Vardhan, Jonah Kudler-Flam, Hassan Shapourian, Hong Liu
Abstract summary: A rich entanglement phase diagram emerges when we generalize this technique to evaluate the logarithmic negativity for various universality classes of macroscopically thermalized states. When applied to evaporating black holes, these results imply that there is quantum entanglement within the Hawking radiation long before the Page time.
Score: 6.040744715321308
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We study the mixed-state entanglement structure of chaotic quantum many-body systems at late times using the recently developed $\textit{equilibrium approximation}$. A rich entanglement phase diagram emerges when we generalize this technique to evaluate the logarithmic negativity for various universality classes of macroscopically thermalized states. Unlike in the infinite temperature case, when we impose energy constraints at finite temperature, the phase diagrams for the logarithmic negativity and the mutual information become distinct. In particular, we identify a regime where the negativity is extensive but the mutual information is sub-extensive, indicating a large amount of $\textit{bound entanglement}$. When applied to evaporating black holes, these results imply that there is quantum entanglement within the Hawking radiation long before the Page time, although this entanglement may not be distillable into EPR pairs.

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