Manipulating single photons from disparate quantum sources to be indistinguishable [Invited]

Glenn S. Solomon; Edward B. Flagg; Sergey V. Polyakov; Tim Thomay; Andreas Muller

doi:10.1364/JOSAB.29.000319

Manipulating single photons from disparate quantum sources to be indistinguishable [Invited]

Glenn S. Solomon
, Edward B. Flagg
, Sergey V. Polyakov
, Tim Thomay
, Andreas Muller

Physics

University of Maryland, College Park
University of South Florida

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

3 Scopus citations

Abstract

Quantum information networks will likely require different quantum systems for different functionality within the network. Indistinguishable photons can be used to interconnect these different subsystems. We discuss methods for coherently manipulating the single photons from different quantum systems and experimentally demonstrate spatial, temporal, and frequency matching of single photons using quantum dot and heralded parametric downconversion single photons. The bosonic nature of light insures that when two indistinguishable photons are superimposed on a beam splitter, they will form a single two-photon state, a process we call coalescence. This coalescence property can be used as both a fundamental test of indistinguishability and in quantum networks - connecting and propagating quantum information.

Original language	English
Pages (from-to)	319-327
Number of pages	9
Journal	Journal of the Optical Society of America B: Optical Physics
Volume	29
Issue number	3
DOIs	https://doi.org/10.1364/JOSAB.29.000319
State	Published - Mar 2012

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title = "Manipulating single photons from disparate quantum sources to be indistinguishable [Invited]",

abstract = "Quantum information networks will likely require different quantum systems for different functionality within the network. Indistinguishable photons can be used to interconnect these different subsystems. We discuss methods for coherently manipulating the single photons from different quantum systems and experimentally demonstrate spatial, temporal, and frequency matching of single photons using quantum dot and heralded parametric downconversion single photons. The bosonic nature of light insures that when two indistinguishable photons are superimposed on a beam splitter, they will form a single two-photon state, a process we call coalescence. This coalescence property can be used as both a fundamental test of indistinguishability and in quantum networks - connecting and propagating quantum information.",

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T1 - Manipulating single photons from disparate quantum sources to be indistinguishable [Invited]

AU - Solomon, Glenn S.

AU - Flagg, Edward B.

AU - Polyakov, Sergey V.

AU - Thomay, Tim

AU - Muller, Andreas

PY - 2012/3

Y1 - 2012/3

N2 - Quantum information networks will likely require different quantum systems for different functionality within the network. Indistinguishable photons can be used to interconnect these different subsystems. We discuss methods for coherently manipulating the single photons from different quantum systems and experimentally demonstrate spatial, temporal, and frequency matching of single photons using quantum dot and heralded parametric downconversion single photons. The bosonic nature of light insures that when two indistinguishable photons are superimposed on a beam splitter, they will form a single two-photon state, a process we call coalescence. This coalescence property can be used as both a fundamental test of indistinguishability and in quantum networks - connecting and propagating quantum information.

AB - Quantum information networks will likely require different quantum systems for different functionality within the network. Indistinguishable photons can be used to interconnect these different subsystems. We discuss methods for coherently manipulating the single photons from different quantum systems and experimentally demonstrate spatial, temporal, and frequency matching of single photons using quantum dot and heralded parametric downconversion single photons. The bosonic nature of light insures that when two indistinguishable photons are superimposed on a beam splitter, they will form a single two-photon state, a process we call coalescence. This coalescence property can be used as both a fundamental test of indistinguishability and in quantum networks - connecting and propagating quantum information.

UR - https://www.scopus.com/pages/publications/84857838309

U2 - 10.1364/JOSAB.29.000319

DO - 10.1364/JOSAB.29.000319

M3 - Article

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JO - Journal of the Optical Society of America B: Optical Physics

JF - Journal of the Optical Society of America B: Optical Physics

IS - 3

ER -

Manipulating single photons from disparate quantum sources to be indistinguishable [Invited]

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