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Banchi, L., Quesada, N., & Arrazola, J. M. (2020). Training Gaussian boson sampling distributions. Physical Review A, 102(1), 012417. Lien externe
Bromley, T. R., Arrazola, J. M., Jahangiri, S., Izaac, J., Quesada, N., Gran, A. D., Schuld, M., Swinarton, J., Zabaneh, Z., & Killoran, N. (2020). Applications of near-term photonic quantum computers: software and algorithms. Quantum Science and Technology, 5(3), 034010. Lien externe
Gupt, B., Arrazola, J. M., Quesada, N., & Bromley, T. R. (2020). Classical benchmarking of Gaussian Boson Sampling on the Titan supercomputer. Quantum Information Processing, 19(8), 249-249. Lien externe
Helt, L. G., & Quesada, N. (2020). Degenerate squeezing in waveguides: a unified theoretical approach. Journal of Physics: Photonics, 2(3), 035001. Lien externe
Jahangiri, S., Arrazola, J. M., Quesada, N., & Delgado, A. (2020). Quantum algorithm for simulating molecular vibrational excitations. Physical Chemistry Chemical Physics, 22(44), 25528-25537. Lien externe
Jahangiri, S., Arrazola, J. M., Quesada, N., & Killoran, N. (2020). Point processes with Gaussian boson sampling. Physical Review E, 101(2), 022134. Lien externe
Killoran, N., Bromley, T. R., Arrazola, J. M., Schuld, M., & Quesada, N. (2020). Apparatus and methods for quantum computing and machine learning. (Demande de brevet no US20200401920). Lien externe
Miatto, F. M., & Quesada, N. (2020). Fast optimization of parametrized quantum optical circuits. Quantum, 4, 366-366. Lien externe
Qi, H., Brod, D. J., Quesada, N., & García-Patrón, R. (2020). Regimes of Classical Simulability for Noisy Gaussian Boson Sampling. Physical Review Letters, 124(10), 100502. Lien externe
Quesada, N., & Arrazola, J. M. (2020). Exact simulation of Gaussian boson sampling in polynomial space and exponential time. Physical Review Research, 2(2), 023005. Lien externe
Quesada, N., Triginer, G., Vidrighin, M. D., & Sipe, J. E. (2020). Theory of high-gain twin-beam generation in waveguides: From Maxwell's equations to efficient simulation. Physical Review A, 102(3), 033519. Lien externe
Triginer, G., Vidrighin, M. D., Quesada, N., Eckstein, A., Moore, M., Kolthammer, W. S., Sipe, J. E., & Walmsley, I. A. (2020). Understanding High-Gain Twin-Beam Sources Using Cascaded Stimulated Emission. Physical Review X, 10(3), 031063. Lien externe
Vaidya, V. D., Morrison, B., Helt, L. G., Shahrokshahi, R., Mahler, D. H., Collins, M. J., Tan, K., Lavoie, J., Repingon, A., Menotti, M., Quesada, N., Pooser, R. C., Lita, A. E., Gerrits, T., Nam, S. W., & Vernon, Z. (2020). Broadband quadrature-squeezed vacuum and nonclassical photon number correlations from a nanophotonic device. Science Advances, 6(39), eaba9186. Lien externe
Vernon, Z., Kang, T. A. N., Morrison, B., Shahrokhshahi, R., Mahler, D., Menotti, M., & Quesada, N. (2020). Integrated devices for squeezed light generation. (Brevet no US10649307). Lien externe
Vidrighin, M. D., Triginer, G., Quesada, N., Eckstein, A., Moore, M., Kolthammer, W. S., Sipe, J. E., & Walmsley, I. A. (mai 2020). High-Gain Twin-Beam Generation in Waveguides: Experimental Characterization Using Cascaded Stimulated Emission [Communication écrite]. Conference on Lasers and Electro-Optics, Washington, D.C.. Lien externe
