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On-chip single photon sources based on quantum dots in photonic crystal structuresSchwagmann, Andre January 2013 (has links)
In order to harness the enormous potential of schemes in optical quantum information processing, readily scalable photonic circuits will be required. A major obstacle for this scalability is the monolithic integration of quantum light sources with the photonic circuit on a single chip. This dissertation presents the experimental demonstration of different in-plane single photon sources that allow for this integration with planar light circuits. To this end, the spontaneous recombination of excitons in single indium arsenide quantum dots was exploited to generate single photons. The emission into on-chip waveguides was achieved by the use of advanced two-dimensional photonic crystal structures. First, slow-light effects in a unidirectional photonic crystal waveguide were exploited to achieve on-demand single photon emission with a rate of up to 18.7 MHz, corresponding to a remarkable estimated internal device efficiency of up to 47%. Waveguide-coupled L3 defect cavities with record Q-factors of up to 5150 were then studied for improved Purcell enhancement of the emission, and in-plane single photon generation from such a device was demonstrated. Finally, an electrically tunable, integrable quantum light source with a total tuning range of 1.9 nm was demonstrated by exploiting the quantum-confined Stark effect in an electrical PIN diode. These results are the first demonstrations of in-plane single photon emission at optical wavelengths and mark an important cornerstone for the realisation of fully integrated quantum photonic circuits in optical quantum information science.
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Femtosecond-laser Written Integrated Optical Devices for Quantum Circuits / Femtosekund-laserskrivna integrerade optiska enheter för kvantkretsarChen, Ang January 2022 (has links)
Integrated quantum photonic circuits have gained increasing interest in the field of quantum information, due to their compactness, the intrinsic stability and the potential scalability. Photons are the promising candidate for quantum information processing. Among all the optical platforms, femtosecond-laser waveguide writing technique has shown the extraordinary versatility in producing different components of a complete quantum system. In the last decade, femtosecond-laser writing has greatly expanded its applications in quantum technology. The aim of this thesis is to study and optimize the fundamental optical devices for integrated quantum circuits using femtosecond-laser waveguide writing technique. We investigate relevant theory of optical waveguides, the methods to fabricate and characterize laser-written waveguides in glass. In this work, we demonstrate the femtosecond-laser writing of integrated devices including Mach-Zehnder interferometer and path-encoded CNOT quantum gate. These devices can further serve as building blocks to produce complete integrated quantum system. / Integrerade kvantfotoniska kretsar har fått ett ökande intresse inom området kvantinformation, på grund av deras kompakthet, den inneboende stabiliteten och den potentiella skalbarheten. Fotoner är den lovande kandidaten för bearbetning av kvantinformation. Bland alla optiska plattformar har femtosekund-laservågledarskrivteknik visat den extraordinära mångsidigheten i att producera olika komponenter i ett komplett kvantsystem. Under det senaste decenniet har femtosekundlaserskrivning kraftigt utökat sina tillämpningar inom kvantteknologi. Syftet med denna avhandling är att studera och optimera de grundläggande optiska enheterna för integrerade kvantkretsar med hjälp av femtosekund-laservågledarskrivteknik. Vi undersöker relevant teori om optiska vågledare, metoderna för att tillverka och karakterisera laserskrivna vågledare i glas. I detta arbete demonstrerar vi femtosekundlaserskrivning av integrerade enheter inklusive Mach-Zehnder-interferometer och vägkodad CNOT-kvantgrind. Dessa enheter kan vidare fungera som byggstenar för att producera kompletta integrerade kvantsystem.
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Quantum Algorithmic Engineering with Photonic Integrated CircuitsKallol, Roy January 2013 (has links) (PDF)
Integrated quantum photonics show monolithic waveguide chips to be a promising platform for realizing the next generation of quantum optical circuits. This work proposes the implementation of quantum page Rank algorithm on a photonic waveguide lattice. Our contributions are as follows: Continuous-time quantum stochastic walk(QSW)-an alternate paradigm of quantum computing, is a hybrid quantum walk that incorporates both unitary and non-unitary effects. We propose the use of QSW which necessitates the hopping of the quantum crawler on a directed graph, for the quantum page Rank problem. We propose the implementation of quantum page Rank on a photonic waveguide lattice, where we allow the density matrix to evolve according to the Lindblad-Kossakowski master equation, the diagonal of which gives the quantum page Rank. We have also shown the use of the metric of positional Kolmogorov Complexity as an efficient tool for determining whether or not the quantum channel has been compromised. We appositionally encode multi-photon decoy pulses within the stream of single photon pulses. This positional encoding is chosen in such a way as to have low Kolmogorov complexity. The PNS attack on the multi-photon decoy pulses causes a dip in the ratio of the transmittance of the decoy pulses to the signal pulses in the conventional analysis.
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