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Dr. Cariñe-Catrileo, Jaime
Nombre de publicación
Dr. Cariñe-Catrileo, Jaime
Nombre completo
Cariñe Catrileo, Jaime Andrés
Facultad
Email
jcarine@ucsc.cl
ORCID
3 results
Research Outputs
Now showing 1 - 3 of 3
- PublicationPost-Measurement adjustment of the coincidence window in quantum optics experiments(IEEE Access, 2021)
; ;Gomez, Santiago A. ;Obregon, Giannini F. ;Gomez, Esteban S. ;Figueroa, Miguel ;Lima, GustavoXavier, GuilhermeWe report on an electronic coincidence detection circuit for quantum photonic applications implemented on a field-programmable gate array (FPGA), which records each the time separation between detection events coming from single-photon detectors. We achieve a coincidence window as narrow as 500 ps with a series of optimizations on a readily-available and affordable FPGA development board. Our implementation allows real-time visualization of coincidence measurements for multiple coincidence window widths simultaneously. To demonstrate the advantage of our high-resolution visualization, we certified the generation of polarized entangled photons by collecting data from multiple coincidence windows with minimal accidental counts, obtaining a violation of the Clauser-Horne-Shimony-Holt (CHSH) Bell inequality by more than 338 standard deviations. Our results have shown the applicability of our electronic design in the field of quantum information. - PublicationComputational advantage from the quantum superposition of multiple temporal orders of photonic gates(American Physical Society, 2021)
;Taddei, Márcio M.; ;Martínez, Daniel ;García, Tania ;Guerrero, Nayda ;Abbott, Alastair A. ;Araújo, Mateus ;Branciard, Cyril ;Gómez, Esteban S. ;Walborn, Stephen P. ;Aolita, LeandroLima, GustavoModels for quantum computation with circuit connections subject to the quantum superposition principle have recently been proposed. In them, a control quantum system can coherently determine the order in which a target quantum system undergoes N gate operations. This process, known as the quantum N-switch, is a resource for several information-processing tasks. In particular, it provides a computational advantage—over fixed-gate-order quantum circuits—for phase-estimation problems involving N unknown unitary gates. However, the corresponding algorithm requires an experimentally unfeasible target-system dimension (super)exponential in N. Here, we introduce a promise problem for which the quantum N-switch gives an equivalent computational speedup with target-system dimension as small as 2 regardless of N. We use state-of-the-art multicore optical-fiber technology to experimentally demonstrate the quantum N-switch with N = 4 gates acting on a photonic-polarization qubit. This is the first observation of a quantum superposition of more than N = 2 temporal orders, demonstrating its usefulness for efficient phase estimation. - PublicationAll-in-Fiber dynamically reconfigurable orbital angular momentum mode sorting(American Chemical Society Photonics, 2023)
;Alarcón, Alvaro ;Gómez, Santiago ;Spegel-Lexne, Daniel ;Argillander, Joakim; ;Cañas, Gustavo ;Lima, GustavoB. Xavier, GuilhermeThe orbital angular momentum (OAM) spatial degree of freedom of light has been widely explored in many applications, including telecommunications, quantum information, and light-based micromanipulation. The ability to separate and distinguish between the different transverse spatial modes is called mode sorting or mode demultiplexing, and it is essential to recover the encoded information in such applications. An ideal d mode sorter should be able to faithfully distinguish between the different d spatial modes, with minimal losses, and have d outputs and fast response times. All previous mode sorters rely on bulk optical elements, such as spatial light modulators, which cannot be quickly tuned and have additional losses if they are to be integrated with optical fiber systems. Here, we propose and experimentally demonstrate, to the best of our knowledge, the first all-in-fiber method for OAM mode sorting with ultrafast dynamic reconfigurability. Our scheme first decomposes the OAM mode in-fiber-optical linearly polarized (LP) modes and then interferometrically recombines them to determine the topological charge, thus correctly sorting the OAM mode. In addition, our setup can also be used to perform ultrafast routing of the OAM modes. These results show a novel and fiber-integrated form of optical spatial mode sorting that can be readily used for many new applications in classical and quantum information processing.