95 research outputs found
Demonstrating multipartite entanglement of single-particle W states: linear optical schemes
We present two linear optical schemes using nonideal photodetectors to
demonstrate inseparability of W-type N-partite entangled states containing only
a single photon. First, we show that the pairwise entanglement of arbitrary two
modes chosen from N optical modes can be detected using the method proposed by
Nha and Kim [Phys. Rev. A 74, 012317 (2006)], thereby suggesting the full
inseparability among N parties. In particular, this scheme is found to succeed
for any nonzero quantum efficiency of photodetectors. Second, we consider a
quantum teleportation network using linear optics without auxiliary modes. The
conditional teleportation can be optimized by a suitable choice of the
transmittance of the beam splitter in the Bell measurement. Specifically, we
identify the conditions under which maximum fidelity larger than classical
bound 2/3 is achieved only in cooperation with other parties. We also
investigate the case of on-off photodetectors that cannot discriminate the
number of detected photons.Comment: 5.5 pages, 2 figures, published version with slight modification
Quantum state engineering by a coherent superposition of photon subtraction and addition
We study a coherent superposition of field annihilation and creation operator
acting on continuous variable systems and propose its application for quantum
state engineering. Specifically, it is investigated how the superposed
operation transforms a classical state to a nonclassical one, together with
emerging nonclassical effects. We also propose an experimental scheme to
implement this elementary coherent operation and discuss its usefulness to
produce an arbitrary superposition of number states involving up to two
photons.Comment: published version, 7 pages, 8 figure
Entropic Uncertainty Relations via Direct-Sum Majorization Relation for Generalized Measurements
We derive an entropic uncertainty relation for generalized
positive-operator-valued measure (POVM) measurements via a direct-sum
majorization relation using Schur concavity of entropic quantities in a
finite-dimensional Hilbert space. Our approach provides a significant
improvement of the uncertainty bound compared with previous majorization-based
approaches [S. Friendland, V. Gheorghiu and G. Gour, Phys. Rev. Lett. 111,
230401 (2013); A. E. Rastegin and K. \.Zyczkowski, J. Phys. A, 49, 355301
(2016)], particularly by extending the direct-sum majorization relation first
introduced in [\L. Rudnicki, Z. Pucha{\l}a and K. \.{Z}yczkowski, Phys. Rev. A
89, 052115 (2014)]. We illustrate the usefulness of our uncertainty relations
by considering a pair of qubit observables in a two-dimensional system and
randomly chosen unsharp observables in a three-dimensional system. We also
demonstrate that our bound tends to be stronger than the generalized
Maassen--Uffink bound with an increase in the unsharpness effect. Furthermore,
we extend our approach to the case of multiple POVM measurements, thus making
it possible to establish entropic uncertainty relations involving more than two
observables
Entanglement condition via su(2) and su(1,1) algebra using Schr{\"o}dinger-Robertson uncertainty relation
The Schr{\"o}dinger-Robertson inequality generally provides a stronger bound
on the product of uncertainties for two noncommuting observables than the
Heisenberg uncertainty relation, and as such, it can yield a stricter
separability condition in conjunction with partial transposition. In this
paper, using the Schr{\"o}dinger-Robertson uncertainty relation, the
separability condition previously derived from the su(2) and the su(1,1)
algebra is made stricter and refined to a form invariant with respect to local
phase shifts. Furthermore, a linear optical scheme is proposed to test this
invariant separability condition.Comment: published version, 3.5 pages, 1 figur
Optimal continuous-variable teleportation under energy constraint
Quantum teleportation is one of the crucial protocols in quantum information
processing. It is important to accomplish an efficient teleportation under
practical conditions, aiming at a higher fidelity desirably using fewer
resources. The continuous-variable (CV) version of quantum teleportation was
first proposed using a Gaussian state as a quantum resource, while other
attempts were also made to improve performance by applying non-Gaussian
operations. We investigate the CV teleportation to find its ultimate fidelity
under energy constraint identifying an optimal quantum state. For this purpose,
we present a formalism to evaluate teleportation fidelity as an expectation
value of an operator. Using this formalism, we prove that the optimal state
must be a form of photon-number entangled states. We further show that Gaussian
states are near-optimal while non-Gaussian states make a slight improvement and
therefore are rigorously optimal, particularly in the low-energy regime.Comment: 8 pages, 4 figures, published versio
Entanglement criteria and nonlocality for multi-mode continuous variable systems
We demonstrate how to efficiently derive a broad class of inequalities for
entanglement detection in multi-mode continuous variable systems. The
separability conditions are established from partial transposition (PT) in
combination with several distinct necessary conditions for a quantum physical
state, which include previously established inequalities as special cases.
Remarkably, our method enables us to support Peres' conjecture to its full
generality within the framework of Cavalcanti-Foster-Reid-Drummond multipartite
Bell inequality [Phys. Rev. Lett. 99}, 210405 (2007)] that the nonlocality
necessarily implies negative PT entangled states.Comment: 4 pages, publishe
Dynamical theory of single photon transport in a one-dimensional waveguide coupled to identical and non-identical emitters
We develop a general dynamical theory for studying a single photon transport
in a one-dimensional (1D) waveguide coupled to multiple emitters which can be
either identical or non-identical. In this theory, both the effects of the
waveguide and non-waveguide vacuum modes are included. This theory enables us
to investigate the propagation of an emitter excitation or an arbitrary single
photon pulse along an array of emitters coupled to a 1D waveguide. The
dipole-dipole interaction induced by the non-waveguide modes, which is usually
neglected in the literatures, can significantly modify the dynamics of the
emitter system as well as the characteristics of output field if the emitter
separation is much smaller than the resonance wavelength. Non-identical
emitters can also strongly couple to each other if their energy difference is
smaller than or of the order of the dipole-dipole energy shift. Interestingly,
if their energy difference is close but non-zero, a very narrow transparency
window around the resonance frequency can appear which does not occur for
identical emitters. This phenomenon may find important applications in quantum
waveguide devices such as optical switch and ultra narrow single photon
frequency comb generator.Comment: 17 pages, 8 figure
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