Photonic circuits with multiple quantum dots: Towards scalable operation of deterministic single-photon sources
Research output: Book/Report › Ph.D. thesis › Research
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Photonic circuits with multiple quantum dots : Towards scalable operation of deterministic single-photon sources. / Papon, Camille.
Niels Bohr Institutet, 2023. 146 p.Research output: Book/Report › Ph.D. thesis › Research
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TY - BOOK
T1 - Photonic circuits with multiple quantum dots
T2 - Towards scalable operation of deterministic single-photon sources
AU - Papon, Camille
PY - 2023
Y1 - 2023
N2 - Single photons represent a major asset for the development of quan- tum technologies, owing to their compatibility with advanced photonic integrated circuits, ultimately enabling the realization of large-scale quantum processors. Generating the necessary large photonic resource requires scaling up integrated deterministic single-photon sources (SPS), a challenging task due to emitter-to-emitter disparity in wavelength and position. Here, we experimentally implement a strategy to control multiple solidstate quantum emitters directly integrated into photonic circuits, to generate multi-photon states on-chip. More specifically, we employ low-noise InAs quantum dots (QD) inte- grated into p-i-n GaAs nanophotonic waveguides, which have been developed over the past few years to generate indistinguishable single photons. The strong-light matter interaction in nanophotonic structures ensures deterministic operation, leading to a high single-photon count rate. Additionally, the planar quantum photonic platform offers the opportunity to integrate the control of SPSs through dedicated circuits, ultimately enabling the realization of a multi-QD circuit. We first demonstrate a small-scale multi-QD photonic circuit enabling the simultaneous operation of two waveguide-integrated SPSs. To do so, we make use of dual-mode waveguides, where one mode is used for ex- citation and the second one for collecting single photons, enabling fully waveguide-based resonant excitation and laser filtering. We optically address these two "plug-and-play" SPSs in parallel using a polarization diversity grating to perform on-chip distribution of a single laser to two QDs. The pair of quantum dots are brought into mutual resonance by applying independent bias voltages across the p-i-n diode with locally-isolated electrical contacts, thereby tuning the QDs emission wavelength individually. Each of the waveguide-integrated QDs exhibit excellent single-photon generation as characterized by g(2)(0) ≪ 0.5. Two-photon quantum interference between the two mutually resonant QDs is measured, with a peak visibility of V = 79 ± 2%, limited by imperfect laser suppression. To overcome this limit, mainly caused by fabrication disorder, we investigate a novel scheme for preparing the mode for excitation in a dualmode waveguide based on asymmetric directional couplers. Owing to the bi-directionality of the single-photon emission, this device represents a natural source of dual-rail encoded qubits emitted by a single QD. This is confirmed by measuring the second-order correlation at the device output ports, characterized by a g(2)(0) < 0.07 in deterministic pulsed excitation. The results demonstrated in this thesis embody a strategy for integrating multiple quantum emitters in photonic integrated circuits, with foreseeable application in quantum simulation and quantum communication.
AB - Single photons represent a major asset for the development of quan- tum technologies, owing to their compatibility with advanced photonic integrated circuits, ultimately enabling the realization of large-scale quantum processors. Generating the necessary large photonic resource requires scaling up integrated deterministic single-photon sources (SPS), a challenging task due to emitter-to-emitter disparity in wavelength and position. Here, we experimentally implement a strategy to control multiple solidstate quantum emitters directly integrated into photonic circuits, to generate multi-photon states on-chip. More specifically, we employ low-noise InAs quantum dots (QD) inte- grated into p-i-n GaAs nanophotonic waveguides, which have been developed over the past few years to generate indistinguishable single photons. The strong-light matter interaction in nanophotonic structures ensures deterministic operation, leading to a high single-photon count rate. Additionally, the planar quantum photonic platform offers the opportunity to integrate the control of SPSs through dedicated circuits, ultimately enabling the realization of a multi-QD circuit. We first demonstrate a small-scale multi-QD photonic circuit enabling the simultaneous operation of two waveguide-integrated SPSs. To do so, we make use of dual-mode waveguides, where one mode is used for ex- citation and the second one for collecting single photons, enabling fully waveguide-based resonant excitation and laser filtering. We optically address these two "plug-and-play" SPSs in parallel using a polarization diversity grating to perform on-chip distribution of a single laser to two QDs. The pair of quantum dots are brought into mutual resonance by applying independent bias voltages across the p-i-n diode with locally-isolated electrical contacts, thereby tuning the QDs emission wavelength individually. Each of the waveguide-integrated QDs exhibit excellent single-photon generation as characterized by g(2)(0) ≪ 0.5. Two-photon quantum interference between the two mutually resonant QDs is measured, with a peak visibility of V = 79 ± 2%, limited by imperfect laser suppression. To overcome this limit, mainly caused by fabrication disorder, we investigate a novel scheme for preparing the mode for excitation in a dualmode waveguide based on asymmetric directional couplers. Owing to the bi-directionality of the single-photon emission, this device represents a natural source of dual-rail encoded qubits emitted by a single QD. This is confirmed by measuring the second-order correlation at the device output ports, characterized by a g(2)(0) < 0.07 in deterministic pulsed excitation. The results demonstrated in this thesis embody a strategy for integrating multiple quantum emitters in photonic integrated circuits, with foreseeable application in quantum simulation and quantum communication.
M3 - Ph.D. thesis
BT - Photonic circuits with multiple quantum dots
PB - Niels Bohr Institutet
ER -
ID: 347422034