A fiber-pigtailed quantum dot device generating indistinguishable photons at GHz clock-rates

Lucas Rickert; Kinga Zołnacz; Daniel A. Vajner; Martin Von Helversen; Sven Rodt; Stephan Reitzenstein; Hanqing Liu; Shulun Li; Haiqiao Ni; Paweł Wyborski; Grzegorz Sȩk; Anna Musiał; Zhichuan Niu; Tobias Heindel

doi:10.1515/nanoph-2024-0519

A fiber-pigtailed quantum dot device generating indistinguishable photons at GHz clock-rates

Lucas Rickert, Kinga Zołnacz, Daniel A. Vajner, Martin Von Helversen, Sven Rodt, Stephan Reitzenstein, Hanqing Liu, Shulun Li, Haiqiao Ni, Paweł Wyborski, Grzegorz Sȩk, Anna Musiał, Zhichuan Niu, Tobias Heindel^*

^*Corresponding author for this work

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Abstract

Solid-state quantum light sources based on semiconductor quantum dots (QDs) are increasingly employed in photonic quantum information applications. Especially when moving towards real-world scenarios outside shielded lab environments, the efficient and robust coupling of nanophotonic devices to single-mode optical fibers offers substantial advantage by enabling "plug-And-play"operation. In this work we present a fiber-pigtailed cavity-enhanced source of flying qubits emitting single indistinguishable photons at clock-rates exceeding 1 GHz. This is achieved by employing a fully deterministic technique for fiber-pigtailing optimized QD-devices based on hybrid circular Bragg grating (hCBG) micro-cavities. The fabricated fiber-pigtailed hCBGs feature emission lifetimes of < 80 ${< } 80$ ps, corresponding to a Purcell factor of ∼9, a suppression of multi-photon emission events with g(2)(0) < 1 %, a photon-indistinguishability > 80 ${ >} 80$ % and a measured single-photon coupling efficiency of 53 % in a high numerical aperture single-mode fiber, corresponding to 1.2 Megaclicks per second at the single-photon detectors under 80 MHz excitation clock-rates. Furthermore, we show that high multi-photon suppression and indistinguishability prevail for excitation clock-rates exceeding 1 GHz. Our results show that Purcell-enhanced fiber-pigtailed quantum light sources based on hCBG cavities are a prime candidate for applications of quantum information science.

Original language	English
Journal	Nanophotonics
Number of pages	14
ISSN	2192-8606
DOIs	https://doi.org/10.1515/nanoph-2024-0519
Publication status	Published - 2025

Keywords

Fiber-coupling
GHz operation
Quantum dot devices
Quantum light generation

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title = "A fiber-pigtailed quantum dot device generating indistinguishable photons at GHz clock-rates",

abstract = "Solid-state quantum light sources based on semiconductor quantum dots (QDs) are increasingly employed in photonic quantum information applications. Especially when moving towards real-world scenarios outside shielded lab environments, the efficient and robust coupling of nanophotonic devices to single-mode optical fibers offers substantial advantage by enabling {"}plug-And-play{"}operation. In this work we present a fiber-pigtailed cavity-enhanced source of flying qubits emitting single indistinguishable photons at clock-rates exceeding 1 GHz. This is achieved by employing a fully deterministic technique for fiber-pigtailing optimized QD-devices based on hybrid circular Bragg grating (hCBG) micro-cavities. The fabricated fiber-pigtailed hCBGs feature emission lifetimes of < 80 ${< } 80$ ps, corresponding to a Purcell factor of ∼9, a suppression of multi-photon emission events with g(2)(0) < 1 %, a photon-indistinguishability > 80 ${ >} 80$ % and a measured single-photon coupling efficiency of 53 % in a high numerical aperture single-mode fiber, corresponding to 1.2 Megaclicks per second at the single-photon detectors under 80 MHz excitation clock-rates. Furthermore, we show that high multi-photon suppression and indistinguishability prevail for excitation clock-rates exceeding 1 GHz. Our results show that Purcell-enhanced fiber-pigtailed quantum light sources based on hCBG cavities are a prime candidate for applications of quantum information science.",

keywords = "Fiber-coupling, GHz operation, Quantum dot devices, Quantum light generation",

author = "Lucas Rickert and Kinga Zo{\l}nacz and Vajner, {Daniel A.} and {Von Helversen}, Martin and Sven Rodt and Stephan Reitzenstein and Hanqing Liu and Shulun Li and Haiqiao Ni and Pawe{\l} Wyborski and Grzegorz Sȩk and Anna Musia{\l} and Zhichuan Niu and Tobias Heindel",

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year = "2025",

doi = "10.1515/nanoph-2024-0519",

language = "English",

journal = "Nanophotonics",

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T1 - A fiber-pigtailed quantum dot device generating indistinguishable photons at GHz clock-rates

AU - Rickert, Lucas

AU - Zołnacz, Kinga

AU - Vajner, Daniel A.

AU - Von Helversen, Martin

AU - Rodt, Sven

AU - Reitzenstein, Stephan

AU - Liu, Hanqing

AU - Li, Shulun

AU - Ni, Haiqiao

AU - Wyborski, Paweł

AU - Sȩk, Grzegorz

AU - Musiał, Anna

AU - Niu, Zhichuan

AU - Heindel, Tobias

PY - 2025

Y1 - 2025

N2 - Solid-state quantum light sources based on semiconductor quantum dots (QDs) are increasingly employed in photonic quantum information applications. Especially when moving towards real-world scenarios outside shielded lab environments, the efficient and robust coupling of nanophotonic devices to single-mode optical fibers offers substantial advantage by enabling "plug-And-play"operation. In this work we present a fiber-pigtailed cavity-enhanced source of flying qubits emitting single indistinguishable photons at clock-rates exceeding 1 GHz. This is achieved by employing a fully deterministic technique for fiber-pigtailing optimized QD-devices based on hybrid circular Bragg grating (hCBG) micro-cavities. The fabricated fiber-pigtailed hCBGs feature emission lifetimes of < 80 ${< } 80$ ps, corresponding to a Purcell factor of ∼9, a suppression of multi-photon emission events with g(2)(0) < 1 %, a photon-indistinguishability > 80 ${ >} 80$ % and a measured single-photon coupling efficiency of 53 % in a high numerical aperture single-mode fiber, corresponding to 1.2 Megaclicks per second at the single-photon detectors under 80 MHz excitation clock-rates. Furthermore, we show that high multi-photon suppression and indistinguishability prevail for excitation clock-rates exceeding 1 GHz. Our results show that Purcell-enhanced fiber-pigtailed quantum light sources based on hCBG cavities are a prime candidate for applications of quantum information science.

AB - Solid-state quantum light sources based on semiconductor quantum dots (QDs) are increasingly employed in photonic quantum information applications. Especially when moving towards real-world scenarios outside shielded lab environments, the efficient and robust coupling of nanophotonic devices to single-mode optical fibers offers substantial advantage by enabling "plug-And-play"operation. In this work we present a fiber-pigtailed cavity-enhanced source of flying qubits emitting single indistinguishable photons at clock-rates exceeding 1 GHz. This is achieved by employing a fully deterministic technique for fiber-pigtailing optimized QD-devices based on hybrid circular Bragg grating (hCBG) micro-cavities. The fabricated fiber-pigtailed hCBGs feature emission lifetimes of < 80 ${< } 80$ ps, corresponding to a Purcell factor of ∼9, a suppression of multi-photon emission events with g(2)(0) < 1 %, a photon-indistinguishability > 80 ${ >} 80$ % and a measured single-photon coupling efficiency of 53 % in a high numerical aperture single-mode fiber, corresponding to 1.2 Megaclicks per second at the single-photon detectors under 80 MHz excitation clock-rates. Furthermore, we show that high multi-photon suppression and indistinguishability prevail for excitation clock-rates exceeding 1 GHz. Our results show that Purcell-enhanced fiber-pigtailed quantum light sources based on hCBG cavities are a prime candidate for applications of quantum information science.

KW - Fiber-coupling

KW - GHz operation

KW - Quantum dot devices

KW - Quantum light generation

U2 - 10.1515/nanoph-2024-0519

DO - 10.1515/nanoph-2024-0519

M3 - Journal article

AN - SCOPUS:85215831791

SN - 2192-8606

JO - Nanophotonics

JF - Nanophotonics

ER -

A fiber-pigtailed quantum dot device generating indistinguishable photons at GHz clock-rates

Abstract

Keywords

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