Efficient recycling strategies for preparing large Fock states from single-photon sources --- Applications to quantum metrology

Fock states are a fundamental resource for many quantum technologies such as quantum metrology. While much progress has been made in single-photon source technologies, preparing Fock states with large photon number remains challenging. We present and analyze a bootstrapped approach for non-determini...

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Veröffentlicht in:	arXiv.org 2018-03
Hauptverfasser:	Motes, Keith R, Mann, Ryan L, Olson, Jonathan P, Studer, Nicholas M, Bergeron, E Annelise, Gilchrist, Alexei, Dowling, Jonathan P, Berry, Dominic W, Rohde, Peter P
Format:	Artikel
Sprache:	eng
Schlagworte:	Fock state Metrology Optical memory (data storage) Physics - Quantum Physics Quantum phenomena Recycling
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creator	Motes, Keith R Mann, Ryan L Olson, Jonathan P Studer, Nicholas M Bergeron, E Annelise Gilchrist, Alexei Dowling, Jonathan P Berry, Dominic W Rohde, Peter P
description	Fock states are a fundamental resource for many quantum technologies such as quantum metrology. While much progress has been made in single-photon source technologies, preparing Fock states with large photon number remains challenging. We present and analyze a bootstrapped approach for non-deterministically preparing large photon-number Fock states by iteratively fusing smaller Fock states on a beamsplitter. We show that by employing state recycling we are able to exponentially improve the preparation rate over conventional schemes, allowing the efficient preparation of large Fock states. The scheme requires single-photon sources, beamsplitters, number-resolved photo-detectors, fast-feedforward, and an optical quantum memory.
doi_str_mv	10.48550/arxiv.1603.00533
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While much progress has been made in single-photon source technologies, preparing Fock states with large photon number remains challenging. We present and analyze a bootstrapped approach for non-deterministically preparing large photon-number Fock states by iteratively fusing smaller Fock states on a beamsplitter. We show that by employing state recycling we are able to exponentially improve the preparation rate over conventional schemes, allowing the efficient preparation of large Fock states. 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subjects	Fock state Metrology Optical memory (data storage) Physics - Quantum Physics Quantum phenomena Recycling
title	Efficient recycling strategies for preparing large Fock states from single-photon sources --- Applications to quantum metrology
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