Entanglement in mesoscopic structures: Role of projection

Lebedev, A. V.; Blatter, G.; Beenakker, C. W. J.; Lesovik, G. B.

doi:10.1103/physrevb.69.235312

Cited by 43 publications

(48 citation statements)

References 23 publications

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“…We project this state to the realization that each detector receives exactly one electron. This process is referred to as postselection [37,38]. Thus, we keep only the terms in Eq.…”

Section: Entanglement a Postselectionmentioning

confidence: 99%

Controllable spin entanglement production in a quantum spin Hall ring

2015

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We study the entanglement production in a quantum spin Hall ring geometry where electrons of opposite spins are emitted in pairs from a source and collected in two different detectors. Postselection of coincidence detector events gives rise to entanglement in the system, measurable through correlations between the outcomes in the detectors. We have chosen a geometry such that the entanglement depends on the dynamical phases picked up by the edge states as they move around the ring. In turn, the dependence of the phases on gate potential and Rashba interaction allows for a precise electrical control of the entanglement production in the ring.

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“…We project this state to the realization that each detector receives exactly one electron. This process is referred to as postselection [37,38]. Thus, we keep only the terms in Eq.…”

Section: Entanglement a Postselectionmentioning

confidence: 99%

Controllable spin entanglement production in a quantum spin Hall ring

2015

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“…Furthermore, this violation is independent of the transparencies T u , T d and hence universal; moreover, the Bell inequality (20) scat onto the spin-entangled component. Thus the origin of the entanglement is found in the post-selection during the crosscorrelation measurement effectuated in the Bell inequality test 6,9 . From an experimental point of view it may be difficult to produce voltage pulses driving exactly one (spinless) particle n = 1.…”

Section: Resultsmentioning

confidence: 99%

“…In this device, spin-entangled electron pairs are generated via the injection of spin-singlet pairs into the source lead from the reservoir 8 . This entanglement is made accessible by splitting the pair into the two leads 'u' and 'd' and subsequent projection (through the Bell measurement) to that part of the wave function describing separated electrons travelling in different leads 8,9 . Rather then quantum pumping with a cyclic potential as in Refs.…”

Section: Introductionmentioning

confidence: 99%

“…Early proposals for structures generating streams of entangled particles exploit the interaction between electrons as a resource for producing entanglement, the pairing interaction in superconductors 1 or the repulsive Coulomb interaction in confined geometries 2,3 . Recently, another class of devices has been suggested which avoids direct interparticle interaction; instead, the entanglement originates from a proper post-selection of orbital 4,5,6 or spin 7,8,9 degrees of freedom. The majority of these proposals deals with the situation where the entangled particles are emitted in a random and uncontrolled fashion, while entanglement on demand is implicit in the scheme proposed in Ref.…”

Section: Introductionmentioning

confidence: 99%

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Generating spin-entangled electron pairs in normal conductors using voltage pulses

2005

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We suggest an operating scheme for the deliberate generation of spin-entangled electron pairs in a normal-metal mesoscopic structure with fork geometry. Voltage pulses with associated Faraday flux equal to one flux unit Φ0 = hc/e drive individual singlet-pairs of electrons towards the beam splitter. The spin-entangled pair is created through a post-selection in the two branches of the fork. We analyze the appearance of entanglement in a Bell inequality test formulated in terms of the number of transmitted electrons with a given spin polarization.

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“…4 for recent review͒; most of them use interaction to create entangled pairs. For noninteracting electrons, the proposals include spatial separation of spin-polarized particles 5,6 or, indeed, edge states in the quantum Hall effect regime. 2,7 We also note that proposals for manifestations of non-Abelian statistics 8,9 rely, in fact, on entanglement of the appropriate quasiparticles.…”

Section: Introductionmentioning

confidence: 99%

Suppression of visibility in a two-electron Mach-Zehnder interferometer

Blanter

Gefen

2007

Phys. Rev. B

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We investigate the suppression of the visibility of Aharonov-Bohm oscillations in a two-electron MachZehnder interferometer that leaves the single-electron current unchanged. In the case when the sources emit either spin-polarized or entangled electrons, partial distinguishability of electrons ͑coming from two different sources͒ suppresses the visibility. Two-particle entanglement may produce behavior similar to "dephasing" of two-particle interferometry.

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Entanglement in mesoscopic structures: Role of projection

Cited by 43 publications

References 23 publications

Controllable spin entanglement production in a quantum spin Hall ring

Controllable spin entanglement production in a quantum spin Hall ring

Generating spin-entangled electron pairs in normal conductors using voltage pulses

Suppression of visibility in a two-electron Mach-Zehnder interferometer

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