Unrestricted generation of pure two-qubit states and entanglement diagnosis by single-qubit tomography

J. Gonzales; P. Sánchez; F. Auccapuclla; B. Miller; M. V. Andrés; F. D.E. Zela

doi:10.1364/OL.44.003310

Unrestricted generation of pure two-qubit states and entanglement diagnosis by single-qubit tomography

J. Gonzales
, P. Sánchez
, F. Auccapuclla
, B. Miller
, M. V. Andrés
, F. D.E. Zela

Sección de Física

Pontifical Catholic Univ. of Peru
University of California at Santa Barbara
University of Valencia

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

We present an experimental proof-of-principle for the generation and detection of pure two-qubit states that have been encoded in degrees of freedom that are common to both classical-light beams and single photons. Our protocol requires performing polarization tomography on a single qubit from a qubit pair. The degree of entanglement in the qubit pair is measured by concurrence, which can be directly extracted from intensity measurements—or photon counting—entering single-qubit polarization tomography.

Original language	English
Pages (from-to)	3310-3313
Number of pages	4
Journal	Optics Letters
Volume	44
Issue number	13
DOIs	https://doi.org/10.1364/OL.44.003310
State	Published - 2019

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10.1364/OL.44.003310

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abstract = "We present an experimental proof-of-principle for the generation and detection of pure two-qubit states that have been encoded in degrees of freedom that are common to both classical-light beams and single photons. Our protocol requires performing polarization tomography on a single qubit from a qubit pair. The degree of entanglement in the qubit pair is measured by concurrence, which can be directly extracted from intensity measurements—or photon counting—entering single-qubit polarization tomography.",

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AU - Andrés, M. V.

AU - Zela, F. D.E.

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N2 - We present an experimental proof-of-principle for the generation and detection of pure two-qubit states that have been encoded in degrees of freedom that are common to both classical-light beams and single photons. Our protocol requires performing polarization tomography on a single qubit from a qubit pair. The degree of entanglement in the qubit pair is measured by concurrence, which can be directly extracted from intensity measurements—or photon counting—entering single-qubit polarization tomography.

AB - We present an experimental proof-of-principle for the generation and detection of pure two-qubit states that have been encoded in degrees of freedom that are common to both classical-light beams and single photons. Our protocol requires performing polarization tomography on a single qubit from a qubit pair. The degree of entanglement in the qubit pair is measured by concurrence, which can be directly extracted from intensity measurements—or photon counting—entering single-qubit polarization tomography.

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Unrestricted generation of pure two-qubit states and entanglement diagnosis by single-qubit tomography

Abstract

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