Abstract
Entanglement plays a prominent role in the study of condensed matter
many-body systems: Entanglement measures not only quantify the possible
use of these systems in quantum information protocols, but also shed
light on their physics. However, exact analytical results remain scarce,
especially for systems out of equilibrium. In this work we examine a
paradigmatic one-dimensional fermionic system that consists of a uniform
tight-binding chain with an arbitrary scattering region near its center,
which is subject to a DC bias voltage at zero temperature. The system is
thus held in a current-carrying nonequilibrium steady state, which can
nevertheless be described by a pure quantum state. Using a
generalization of the Fisher-Hartwig conjecture, we present an exact
calculation of the bipartite entanglement entropy of a subsystem with
its complement, and show that the scaling of entanglement with the
length of the subsystem is highly unusual, containing both a volume-law
linear term and a logarithmic term. The linear term is related to
imperfect transmission due to scattering, and provides a generalization
of the Levitov-Lesovik full counting statistics formula. The logarithmic
term arises from the Fermi discontinuities in the distribution function.
Our analysis also produces an exact expression for the
particle-number-resolved entanglement. We find that although to leading
order entanglement equipartition applies, the first term breaking it
grows with the size of the subsystem, a novel behavior not observed in
previously studied systems. We apply our general results to a concrete
model of a tight-binding chain with a single impurity site, and show
that the analytical expressions are in good agreement with numerical
calculations. The analytical results are further generalized to
accommodate the case of multiple scattering regions.
Funder
United States - Israel Binational Science Foundation
Subject
General Physics and Astronomy
Cited by
49 articles.
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