Photonic Quantum Information Processing with Quantum Dot Single-Photon Sources
Research output: Book/Report › Ph.D. thesis › Research
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Photonic Quantum Information Processing with Quantum Dot Single-Photon Sources. / Sund, Patrik Isene.
Niels Bohr Institute, Faculty of Science, University of Copenhagen, 2024. 195 p.Research output: Book/Report › Ph.D. thesis › Research
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TY - BOOK
T1 - Photonic Quantum Information Processing with Quantum Dot Single-Photon Sources
AU - Sund, Patrik Isene
PY - 2024
Y1 - 2024
N2 - The fundamentally quantum mechanical properties of single photons present an exciting opportunity for the development of new technology. The fragile nature of quantum states makes this a challenging prospect, pressing stringent demands on the hardware used to generate and process the light. In this context, semiconductor quantum dots are emerging as a promising platform, enabling the realization of highly-efficient sources of near-identical single photons. In this thesis, we aim to expand the capabilities offered by these sources and state-of-the-art photonic technology. We present novel specialized interferometer architectures developed for the time-bin encoding naturally produced by quantum-dot single-photon sources (SPSs), that allow for significant reductions in loss. We proceed to leverage the advantageous properties of the time-bin encoding by constructing a resource-efficient interferometer used in an experimental demonstration of bosonic suppression laws and postselected entanglement using photons emitted from a quantum-dot SPS. Shifting the focus to photonic integrated circuits, we design a lithium-niobate-on-insulator (LNOI) chip tailored to the emission wavelength of our quantum dots. We perform two-photon interference experiments on two-mode and four-mode interferometers, carrying out the first demonstration of the Hong–Ou–Mandel effect on LNOI. Furthermore, we leverage the fast electro-optic modulators on LNOI to realize an on-chip demultiplexer, which is used to demonstrate active demultiplexing of the single-photon source. Finally, we extend the scope to larger scales by analyzing the hardware requirements for a quantum advantage demonstrations using the boson sampling algorithm with photons emitted from a quantum-dot SPS, determining it to be within reach for current stateof-the-art hardware.
AB - The fundamentally quantum mechanical properties of single photons present an exciting opportunity for the development of new technology. The fragile nature of quantum states makes this a challenging prospect, pressing stringent demands on the hardware used to generate and process the light. In this context, semiconductor quantum dots are emerging as a promising platform, enabling the realization of highly-efficient sources of near-identical single photons. In this thesis, we aim to expand the capabilities offered by these sources and state-of-the-art photonic technology. We present novel specialized interferometer architectures developed for the time-bin encoding naturally produced by quantum-dot single-photon sources (SPSs), that allow for significant reductions in loss. We proceed to leverage the advantageous properties of the time-bin encoding by constructing a resource-efficient interferometer used in an experimental demonstration of bosonic suppression laws and postselected entanglement using photons emitted from a quantum-dot SPS. Shifting the focus to photonic integrated circuits, we design a lithium-niobate-on-insulator (LNOI) chip tailored to the emission wavelength of our quantum dots. We perform two-photon interference experiments on two-mode and four-mode interferometers, carrying out the first demonstration of the Hong–Ou–Mandel effect on LNOI. Furthermore, we leverage the fast electro-optic modulators on LNOI to realize an on-chip demultiplexer, which is used to demonstrate active demultiplexing of the single-photon source. Finally, we extend the scope to larger scales by analyzing the hardware requirements for a quantum advantage demonstrations using the boson sampling algorithm with photons emitted from a quantum-dot SPS, determining it to be within reach for current stateof-the-art hardware.
M3 - Ph.D. thesis
BT - Photonic Quantum Information Processing with Quantum Dot Single-Photon Sources
PB - Niels Bohr Institute, Faculty of Science, University of Copenhagen
ER -
ID: 395824717