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Your search keyword '"Tsintzos, Symeon I."' showing total 9 results
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9 results on '"Tsintzos, Symeon I."'

1. Encoding arbitrary Ising Hamiltonians on Spatial Photonic Ising Machines

Author

Sakellariou, Jason, Askitopoulos, Alexis, Pastras, Georgios, and Tsintzos, Symeon I.

Subjects
Physics - Optics, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Emerging Technologies, Quantum Physics
Abstract

Photonic Ising Machines constitute an emergent new paradigm of computation, geared towards tackling combinatorial optimization problems that can be reduced to the problem of finding the ground state of an Ising model. Spatial Photonic Ising Machines have proven to be advantageous for simulating fully connected large-scale spin systems. However, fine control of a general interaction matrix $J$ has so far only been accomplished through eigenvalue decomposition methods that either limit the scalability or increase the execution time of the optimization process. We introduce and experimentally validate a SPIM instance that enables direct control over the full interaction matrix, enabling the encoding of Ising Hamiltonians with arbitrary couplings and connectivity. We demonstrate the conformity of the experimentally measured Ising energy with the theoretically expected values and then proceed to solve both the unweighted and weighted graph partitioning problems, showcasing a systematic convergence to an optimal solution via simulated annealing. Our approach greatly expands the applicability of SPIMs for real-world applications without sacrificing any of the inherent advantages of the system, and paves the way to encoding the full range of NP problems that are known to be equivalent to Ising models, on SPIM devices., Comment: 7 pages, 4 figures

Published
2024

4. Coupling Nanowire Quantum Dots to Optical Waveguides by Microsphere-Induced Photonic Nanojet

Author

Tsintzos, Symeon I., Tsimvrakidis, Konstantinos, Gates, James C., Elshaari, Ali W., Smith, Peter G.R., Zwiller, Val, Riziotis, Christos, Tsintzos, Symeon I., Tsimvrakidis, Konstantinos, Gates, James C., Elshaari, Ali W., Smith, Peter G.R., Zwiller, Val, and Riziotis, Christos

Abstract

Silica-on-silicon is a major optical integration platform, while the emergent class of the integrated laser-written circuits’ platform offers additionally high customizability and flexibility for rapid prototyping. However, the inherent waveguides’ low core/cladding refractive index contrast characteristic, compared to other photonic platforms in silicon or silicon nitride, sets serious limitations for on-chip efficient coupling with single photon emitters, like semiconductor nanowires with quantum dots, limiting the applications in quantum computing. A new light coupling scheme proposed here overcomes this limitation, providing means for light coupling >50%. The scheme is based on the incorporation of an optical microsphere between the nanowire and the waveguide, which is properly optimized and arranged in terms of size, refractive index, and the distance of the microsphere between the nanowire and waveguide. Upon suitable design of the optical arrangement, the photonic nanojet emitted by the illuminated microsphere excites efficiently the guided eigenmodes of the input channel waveguide, thus launching light with high-coupling efficiency. The method is tolerant in displacements, misalignments, and imperfections and is fabricationally feasible by the current state of art techniques. The proposed method enables the on-chip multiple single photon emitters’ integration, thus allowing for the development of highly customizable and scalable quantum photonic-integrated circuits for quantum computing and communications., QC 20240516

Published
2024
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5. Enabling light coupling between nanowires and low refractive index contrast optical waveguides towards scalable quantum circuits

Author

Tsintzos, Symeon I., Tsimvrakidis, Konstantinos, Sinani, Alexandra, Gates, James C., Elshaari, Ali W., Smith, Peter, Zwiller, Val, Riziotis, Christos, Tsintzos, Symeon I., Tsimvrakidis, Konstantinos, Sinani, Alexandra, Gates, James C., Elshaari, Ali W., Smith, Peter, Zwiller, Val, and Riziotis, Christos

Abstract

A primary constraint in the major photonic integration platform of Silica-on-Silicon, especially when combined with fabrication approaches like Direct Laser Writing is the optical waveguides' low refractive index contrast, leading thus to limitations for efficient coupling with currently available state-of-the-art single photon emitters such as semiconductor nanowires with quantum dots (NWQD). We propose and demonstrate a novel approach to drastically enhance the light coupling between silica based Laser-written channel waveguides and NWQDs, by incorporating an optical microsphere in their intermediate space. It is demonstrated that the induced photonic nanojet action of a suitably designed microsphere illuminated by the NWQD, excites efficiently the channel waveguide's modes and can enable light coupling to a degree even above 50%. The proposed method is reasonably robust to imperfections and misalignments and could be implemented by current state-of-the-art micro/nano patterning techniques. It is anticipated that the practical implementation of the method will allow the integration of multiple quantum emitters in silica based hybrid integrated circuits thus enabling their scalability towards for quantum computing and sensing applications., QC 20240530

Published
2024
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