Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives

Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives

User-friendly single-photon sources with high photon-extraction efficiency are crucial building blocks for photonic quantum applications. For many of these applications, such as long-distance quantum key distribution, the use of single-mode optical fibers is mandatory, which leads to stringent requi...

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Main Authors: Lucas Bremer, Ksenia Weber, Sarah Fischbach, Simon Thiele, Marco Schmidt, Arsenty Kaganskiy, Sven Rodt, Alois Herkommer, Marc Sartison, Simone Luca Portalupi, Peter Michler, Harald Giessen, Stephan Reitzenstein
Format: Article
Language:English
Published: AIP Publishing LLC 2020-10-01
Series:APL Photonics
Online Access:http://dx.doi.org/10.1063/5.0014921
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spelling doaj-ac5ab6cbde32447dabcc2da9000abc072020-11-25T03:45:10ZengAIP Publishing LLCAPL Photonics2378-09672020-10-01510106101106101-810.1063/5.0014921Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectivesLucas Bremer0Ksenia Weber1Sarah Fischbach2Simon Thiele3Marco Schmidt4Arsenty Kaganskiy5Sven Rodt6Alois Herkommer7Marc Sartison8Simone Luca Portalupi9Peter Michler10Harald Giessen11Stephan Reitzenstein12Institute of Solid State Physics, Technische Universität Berlin, Berlin, Germany4th Physics Institute and Research Center SCoPE and Integrated Quantum Science and Technology Center IQST, University of Stuttgart, Stuttgart, GermanyInstitute of Solid State Physics, Technische Universität Berlin, Berlin, GermanyInstitute for Applied Optics (ITO) and Research Center SCoPE, University of Stuttgart, Stuttgart, GermanyInstitute of Solid State Physics, Technische Universität Berlin, Berlin, GermanyInstitute of Solid State Physics, Technische Universität Berlin, Berlin, GermanyInstitute of Solid State Physics, Technische Universität Berlin, Berlin, GermanyInstitute for Applied Optics (ITO) and Research Center SCoPE, University of Stuttgart, Stuttgart, GermanyInstitut für Halbleiteroptik und Funktionelle Grenzflächen, Center for Integrated Quantum Science and Technology (IQST) and Research Center SCoPE, University of Stuttgart, Stuttgart, GermanyInstitut für Halbleiteroptik und Funktionelle Grenzflächen, Center for Integrated Quantum Science and Technology (IQST) and Research Center SCoPE, University of Stuttgart, Stuttgart, GermanyInstitut für Halbleiteroptik und Funktionelle Grenzflächen, Center for Integrated Quantum Science and Technology (IQST) and Research Center SCoPE, University of Stuttgart, Stuttgart, Germany4th Physics Institute and Research Center SCoPE and Integrated Quantum Science and Technology Center IQST, University of Stuttgart, Stuttgart, GermanyInstitute of Solid State Physics, Technische Universität Berlin, Berlin, GermanyUser-friendly single-photon sources with high photon-extraction efficiency are crucial building blocks for photonic quantum applications. For many of these applications, such as long-distance quantum key distribution, the use of single-mode optical fibers is mandatory, which leads to stringent requirements regarding the device design and fabrication. We report on the on-chip integration of a quantum dot (QD) microlens with a 3D-printed micro-objective in combination with a single-mode on-chip fiber coupler. The practical quantum device is realized by the deterministic fabrication of the QD-microlens via in situ electron-beam lithography and the 3D two-photon laser writing of the on-chip micro-objective and fiber chuck. A QD with a microlens is an efficient single-photon source, whose emission is collimated by the on-chip micro-objective. A second polymer microlens is located at the end facet of the single-mode fiber and ensures that the collimated light is efficiently coupled into the fiber core. For this purpose, the fiber is placed in an on-chip fiber chuck, which is precisely aligned to the QD-microlens thanks to the sub-micrometer processing accuracy of high-resolution two-photon direct laser writing. The resulting quantum device has a broadband photon extraction efficiency, a single-mode fiber-coupling efficiency of 22%, a measured single-photon flux of 42 kHz (8.9 kHz) under cw (pulsed) optical excitation, which corresponds to 1.5 MHz (0.3 MHz) at the single-mode fiber output, and a multi-photon probability in terms of g(2)(0) = 0.00±0.000.04 (0.13 ± 0.05) under cw (pulsed) optical excitation. The stable design of the developed fiber-coupled quantum device makes it highly attractive for integration into user-friendly plug-and-play quantum applications.http://dx.doi.org/10.1063/5.0014921
collection DOAJ
language English
format Article
sources DOAJ
author Lucas Bremer
Ksenia Weber
Sarah Fischbach
Simon Thiele
Marco Schmidt
Arsenty Kaganskiy
Sven Rodt
Alois Herkommer
Marc Sartison
Simone Luca Portalupi
Peter Michler
Harald Giessen
Stephan Reitzenstein
spellingShingle Lucas Bremer
Ksenia Weber
Sarah Fischbach
Simon Thiele
Marco Schmidt
Arsenty Kaganskiy
Sven Rodt
Alois Herkommer
Marc Sartison
Simone Luca Portalupi
Peter Michler
Harald Giessen
Stephan Reitzenstein
Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives
APL Photonics
author_facet Lucas Bremer
Ksenia Weber
Sarah Fischbach
Simon Thiele
Marco Schmidt
Arsenty Kaganskiy
Sven Rodt
Alois Herkommer
Marc Sartison
Simone Luca Portalupi
Peter Michler
Harald Giessen
Stephan Reitzenstein
author_sort Lucas Bremer
title Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives
title_short Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives
title_full Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives
title_fullStr Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives
title_full_unstemmed Quantum dot single-photon emission coupled into single-mode fibers with 3D printed micro-objectives
title_sort quantum dot single-photon emission coupled into single-mode fibers with 3d printed micro-objectives
publisher AIP Publishing LLC
series APL Photonics
issn 2378-0967
publishDate 2020-10-01
description User-friendly single-photon sources with high photon-extraction efficiency are crucial building blocks for photonic quantum applications. For many of these applications, such as long-distance quantum key distribution, the use of single-mode optical fibers is mandatory, which leads to stringent requirements regarding the device design and fabrication. We report on the on-chip integration of a quantum dot (QD) microlens with a 3D-printed micro-objective in combination with a single-mode on-chip fiber coupler. The practical quantum device is realized by the deterministic fabrication of the QD-microlens via in situ electron-beam lithography and the 3D two-photon laser writing of the on-chip micro-objective and fiber chuck. A QD with a microlens is an efficient single-photon source, whose emission is collimated by the on-chip micro-objective. A second polymer microlens is located at the end facet of the single-mode fiber and ensures that the collimated light is efficiently coupled into the fiber core. For this purpose, the fiber is placed in an on-chip fiber chuck, which is precisely aligned to the QD-microlens thanks to the sub-micrometer processing accuracy of high-resolution two-photon direct laser writing. The resulting quantum device has a broadband photon extraction efficiency, a single-mode fiber-coupling efficiency of 22%, a measured single-photon flux of 42 kHz (8.9 kHz) under cw (pulsed) optical excitation, which corresponds to 1.5 MHz (0.3 MHz) at the single-mode fiber output, and a multi-photon probability in terms of g(2)(0) = 0.00±0.000.04 (0.13 ± 0.05) under cw (pulsed) optical excitation. The stable design of the developed fiber-coupled quantum device makes it highly attractive for integration into user-friendly plug-and-play quantum applications.
url http://dx.doi.org/10.1063/5.0014921
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