93 research outputs found
Compatibility in multiparameter quantum metrology
Simultaneous estimation of multiple parameters in quantum metrological models
is complicated by factors relating to the (i) existence of a single probe state
allowing for optimal sensitivity for all parameters of interest, (ii) existence
of a single measurement optimally extracting information from the probe state
on all the parameters, and (iii) statistical independence of the estimated
parameters. We consider the situation when these concerns present no obstacle
and for every estimated parameter the variance obtained in the multiparameter
scheme is equal to that of an optimal scheme for that parameter alone, assuming
all other parameters are perfectly known. We call such models compatible. In
establishing a rigorous theoretical framework for investigating compatibility,
we clarify some ambiguities and inconsistencies present in the literature and
discuss several examples to highlight interesting features of unitary and
non-unitary parameter estimation, as well as deriving new bounds for physical
problems of interest, such as the simultaneous estimation of phase and local
dephasing.Comment: v2: Corrected form of the Holevo Cramer-Rao bound, other minor fixe
Quantum state decorrelation
We address the general problem of removing correlations from quantum states
while preserving local quantum information as much as possible. We provide a
complete solution in the case of two qubits, by evaluating the minimum amount
of noise that is necessary to decorrelate covariant sets of bipartite states.
We show that two harmonic oscillators in arbitrary Gaussian state can be
decorrelated by a Gaussian covariant map. Finally, for finite-dimensional
Hilbert spaces, we prove that states obtained from most cloning channels (e.g.,
universal and phase-covariant cloning) can be decorrelated only at the expense
of a complete erasure of information about the copied state. More generally, in
finite dimension, cloning without correlations is impossible for continuous
sets of states. On the contrary, for continuos variables cloning, a slight
modification of the customary set-up for cloning coherent states allows one to
obtain clones without correlations.Comment: 11 pages, 2 figures, RevTex
Evaluable multipartite entanglement measures: are multipartite concurrences entanglement monotones?
We discuss the monotonicity under local operations and classical
communication (LOCC) of systematically constructed quantities aiming at
quantification of entanglement properties of multipartite quantum systems. The
so-called generalized multipartite concurrences can qualify as legitimate
entanglement measures if they are monotonous under LOCC. In the paper we give a
necessary and sufficient criterion for their monotonicity.Comment: 7 pages, 1 figure, minor changes - clarity of proofs improve
Experimental generation of complex noisy photonic entanglement
We present an experimental scheme based on spontaneous parametric
down-conversion to produce multiple photon pairs in maximally entangled
polarization states using an arrangement of two type-I nonlinear crystals. By
introducing correlated polarization noise in the paths of the generated photons
we prepare mixed entangled states whose properties illustrate fundamental
results obtained recently in quantum information theory, in particular those
concerning bound entanglement and privacy.Comment: 12 pages, 3 figure
Quantum Fisher information as a predictor of decoherence in the preparation of spin-cat states for quantum metrology
In its simplest form, decoherence occurs when a quantum state is entangled with a second state, but the results of measurements made on the second state are not accessible. As the second state has effectively “measured” the first, in this paper we argue that the quantum Fisher information is the relevant metric for predicting and quantifying this kind of decoherence. The quantum Fisher information is usually used to determine an upper bound on how precisely measurements on a state can be used to estimate a classical parameter, and as such it is an important resource. Quantum-enhanced metrology aims to create nonclassical states with large quantum Fisher information and utilize them in precision measurements. In the process of doing this it is possible for states to undergo decoherence; for instance atom-light interactions used to create coherent superpositions of atomic states may result in atom-light entanglement. Highly nonclassical states, such as spin-cat states (Schrödinger cat states constructed from superpositions of collective spins) are shown to be highly susceptible to this kind of decoherence. We also investigate the required field occupation of the second state, such that this decoherence is negligible
Experimental Extraction of Secure Correlations from a Noisy Private State
We report experimental generation of a noisy entangled four-photon state that
exhibits a separation between the secure key contents and distillable
entanglement, a hallmark feature of the recently established quantum theory of
private states. The privacy analysis, based on the full tomographic
reconstruction of the prepared state, is utilized in a proof-of-principle key
generation. The inferiority of distillation-based strategies to extract the key
is exposed by an implementation of an entanglement distillation protocol for
the produced state.Comment: 5 pages, 3 figures, final versio
How to hide a secret direction
We present a procedure to share a secret spatial direction in the absence of
a common reference frame using a multipartite quantum state. The procedure
guarantees that the parties can determine the direction if they perform joint
measurements on the state, but fail to do so if they restrict themselves to
local operations and classical communication (LOCC). We calculate the fidelity
for joint measurements, give bounds on the fidelity achievable by LOCC, and
prove that there is a non-vanishing gap between the two of them, even in the
limit of infinitely many copies. The robustness of the procedure under particle
loss is also studied. As a by-product we find bounds on the probability of
discriminating by LOCC between the invariant subspaces of total angular
momentum N/2 and N/2-1 in a system of N elementary spins.Comment: 4 pages, 1 figur
Pumped-Up SU(1,1) interferometry
Although SU(1,1) interferometry achieves Heisenberg-limited sensitivities, it suffers from one major drawback: Only those particles outcoupled from the pump mode contribute to the phase measurement. Since the number of particles outcoupled to these “side modes” is typically small, this limits the interferometer’s absolute sensitivity. We propose an alternative “pumped-up” approach where all the input particles participate in the phase measurement and show how this can be implemented in spinor Bose-Einstein condensates and hybrid atom-light systems—both of which have experimentally realized SU(1,1) interferometry. We demonstrate that pumped-up schemes are capable of surpassing the shot-noise limit with respect to the total number of input particles and are never worse than conventional SU(1,1) interferometry. Finally, we show that pumped-up schemes continue to excel—both absolutely and in comparison to conventional SU(1,1) interferometry—in the presence of particle losses, poor particle-resolution detection, and noise on the relative phase difference between the two side modes. Pumped-up SU(1,1) interferometry therefore pushes the advantages of conventional SU(1,1) interferometry into the regime of high absolute sensitivity, which is a necessary condition for useful quantum-enhanced devices
Enhancing a phase measurement by sequentially probing a solid-state system
In a recent paper, Liu et al. [Nat. Commun. 6:6726 (2015)] claim to perform
the first room temperature entanglement-enhanced phase measurement in a
solid-state system. We argue here that this claim is incorrect: their
measurement is not enhanced because of the entanglement in their system, but
instead the enhancement comes from the fact that the phase shift is applied
twice to their state.Comment: 2 page
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