Geometric Quantum Information Structure in Quantum Fields and their Lattice Simulation
Abstract
An upper limit to distillable entanglement between two disconnected regions of massless non-interacting scalar field theory has an exponential decay defined by a geometric decay constant. When regulated at short distances with a spatial lattice, this entanglement abruptly vanishes beyond a dimensionless separation, defining a negativity sphere. In two spatial dimensions, we determine this geometric decay constant between a pair of disks and the growth of the negativity sphere toward the continuum through a series of lattice calculations. Making the connection to quantum field theories in three-spatial dimensions, assuming such quantum information scales appear also in quantum chromodynamics (QCD), a new relative scale may be present in effective field theories describing the low-energy dynamics of nucleons and nuclei. We highlight potential impacts of the distillable entanglement structure on effective field theories, lattice QCD calculations and future quantum simulations.
Cite
@article{arxiv.2008.03647,
title = {Geometric Quantum Information Structure in Quantum Fields and their Lattice Simulation},
author = {Natalie Klco and Martin J. Savage},
journal= {arXiv preprint arXiv:2008.03647},
year = {2021}
}
Comments
9 pages, 3 figures