96 research outputs found
Bell correlations at finite temperature
We show that spin systems with infinite-range interactions can violate at
thermal equilibrium a multipartite Bell inequality, up to a finite critical
temperature . Our framework can be applied to a wide class of spin systems
and Bell inequalities, to study whether nonlocality occurs naturally in quantum
many-body systems close to the ground state. Moreover, we also show that the
low-energy spectrum of the Bell operator associated to such systems can be well
approximated by the one of a quantum harmonic oscillator, and that
spin-squeezed states are optimal in displaying Bell correlations for such Bell
inequalities.Comment: 9 pages (7 + Appendix), 2 figures. Version accepted for publication
in Quantu
Bounding the Set of Classical Correlations of a Many-Body System
We present a method to certify the presence of Bell correlations in experimentally observed statistics, and to obtain new Bell inequalities. Our approach is based on relaxing the conditions defining the set of correlations obeying a local hidden variable model, yielding a convergent hierarchy of semidefinite programs (SDP's). Because the size of these SDP's is independent of the number of parties involved, this technique allows us to characterize correlations in many-body systems. As an example, we illustrate our method with the experimental data presented in Science 352, 441 (2016)
Tropical contraction of tensor networks as a Bell inequality optimization toolset
We show that finding the classical bound of broad families of Bell
inequalities can be naturally framed as the contraction of an associated tensor
network, but in tropical algebra, where the sum is replaced by the minimum and
the product is replaced by the arithmetic addition. We illustrate our method
with paradigmatic examples both in the multipartite scenario and the bipartite
scenario with multiple outcomes. We showcase how the method extends into the
thermodynamic limit for some translationally invariant systems and establish a
connection between the notions of tropical eigenvalue and the classical bound
per particle as a fixed point of a tropical renormalization procedure.Comment: 6 pages, 4 figure
Maximal nonlocality from maximal entanglement and mutually unbiased bases, and self-testing of two-qutrit quantum systems
Bell inequalities are an important tool in device-independent quantum
information processing because their violation can serve as a certificate of
relevant quantum properties. Probably the best known example of a Bell
inequality is due to Clauser, Horne, Shimony and Holt (CHSH), which is defined
in the simplest scenario involving two dichotomic measurements and whose all
key properties are well understood. There have been many attempts to generalise
the CHSH Bell inequality to higher-dimensional quantum systems, however, for
most of them the maximal quantum violation---the key quantity for most
device-independent applications---remains unknown. On the other hand, the
constructions for which the maximal quantum violation can be computed, do not
preserve the natural property of the CHSH inequality, namely, that the maximal
quantum violation is achieved by the maximally entangled state and measurements
corresponding to mutually unbiased bases. In this work we propose a novel
family of Bell inequalities which exhibit precisely these properties, and whose
maximal quantum violation can be computed analytically. In the simplest
scenario it recovers the CHSH Bell inequality. These inequalities involve
measurements settings, each having outcomes for an arbitrary prime number
. We then show that in the three-outcome case our Bell inequality can
be used to self-test the maximally entangled state of two-qutrits and three
mutually unbiased bases at each site. Yet, we demonstrate that in the case of
more outcomes, their maximal violation does not allow for self-testing in the
standard sense, which motivates the definition of a new weak form of
self-testing. The ability to certify high-dimensional MUBs makes these
inequalities attractive from the device-independent cryptography point of view.Comment: 19 pages, no figures, accepted in Quantu
Bounding the fidelity of quantum many-body states from partial information
We formulate an algorithm to lower bound the fidelity between quantum
many-body states only from partial information, such as the one accessible by
few-body observables. Our method is especially tailored to permutationally
invariant states, but it gives nontrivial results in all situations where this
symmetry is even partial. This property makes it particularly useful for
experiments with atomic ensembles, where relevant many-body states can be
certified from collective measurements. As an example, we show that a
spin squeezed state of particles can be
certified with a fidelity up to , only from the measurement of its
polarization and of its squeezed quadrature. Moreover, we show how to
quantitatively account for both measurement noise and partial symmetry in the
states, which makes our method useful in realistic experimental situations.Comment: comments are welcom
The quantum marginal problem for symmetric states: applications to variational optimization, nonlocality and self-testing
In this paper, we present a method to solve the quantum marginal problem for symmetric d-level systems. The method is built upon an efficient semi-definite program that uses the compatibility conditions of an m-body reduced density with a global n-body density matrix supported on the symmetric space. We illustrate the applicability of the method in central quantum information problems with several exemplary case studies. Namely, (i) a fast variational ansatz to optimize local Hamiltonians over symmetric states, (ii) a method to optimize symmetric, few-body Bell operators over symmetric states and (iii) a set of sufficient conditions to determine which symmetric states cannot be self-tested from few-body observables. As a by-product of our findings, we also provide a generic, analytical correspondence between arbitrary superpositions of n-qubit Dicke states and translationally-invariant diagonal matrix product states of bond dimension n
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