Energy cost of entanglement extraction in complex quantum systems

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Authors

  • Cédric Bény
  • Christopher T. Chubb
  • Terry Farrelly
  • Tobias J. Osborne

Research Organisations

External Research Organisations

  • Hanyang University
  • University of Sydney
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Details

Original languageEnglish
Article number3792
JournalNature Communications
Volume9
Publication statusPublished - 17 Sept 2018

Abstract

What is the energy cost of extracting entanglement from complex quantum systems? Operationally, we may wish to actually extract entanglement. Conceptually, we may wish to physically understand the entanglement distribution as a function of energy. This is important, especially for quantum field theory vacua, which are extremely entangled. Here we build a theory to understand the energy cost of entanglement extraction. First, we consider a toy model, and then we define the entanglement temperature, relating energy cost to extracted entanglement. Next, we give a physical argument quantifying the energy cost of entanglement extraction in some quantum field vacua. There the energy cost depends on the spatial dimension: in one dimension, for example, it grows exponentially with extracted entanglement. Next, we provide approaches to bound the energy cost of extracting entanglement more generally. Finally, we look at spin chain models numerically to calculate the entanglement temperature using matrix product states.

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Cite this

Energy cost of entanglement extraction in complex quantum systems. / Bény, Cédric; Chubb, Christopher T.; Farrelly, Terry et al.
In: Nature Communications, Vol. 9, 3792, 17.09.2018.

Research output: Contribution to journalArticleResearchpeer review

Bény C, Chubb CT, Farrelly T, Osborne TJ. Energy cost of entanglement extraction in complex quantum systems. Nature Communications. 2018 Sept 17;9:3792. doi: 10.48550/arXiv.1711.06658, 10.1038/s41467-018-06153-w, 10.15488/4224
Bény, Cédric ; Chubb, Christopher T. ; Farrelly, Terry et al. / Energy cost of entanglement extraction in complex quantum systems. In: Nature Communications. 2018 ; Vol. 9.
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