Areas of expertise
Quantum imaging
Professor
Énergie Matériaux Télécommunications Research Centre
1650 Lionel-Boulet Blvd.
Varennes, Quebec J3X 1P7
Canada
Research interests
Professor Bienvenu Ndagano’s research program focuses on exploiting the multi-dimensional properties of photons for communication, imaging and sensing purposes. In particular, this research program explores:
- Engineering of entangled states in the spatial and temporal domain
- Transport of entangled states in complex media
- Quantum microscopy
- Detection of entangled states in high dimensions
- Imaging of quantum correlations
- Quantum sensing assisted by non-linear processes
- Non-linear transfer of quantum entanglement in high-dimension
(a) Engineered sample etched in glass and measured with a profilometer. (b) The sample is not visible on the intensity image after illumination. (c) Low-resolution correlation image of the sample obtained from coincidence counting. (d) High-resolution correlation image of the sample obtained from combining low resolution images of the sample shifted transversally. (e) depth profile of the sample estimated from the high-resolution correlation image. Nature Photonics 16, 384–389 (2022)
(a) Two equivalent quantum and classical scenarios in which Alice send a photon from a non-separable state; in the quantum picture, Alice sends a photon from an entangled pair while in the classical picture, she sends one photon, of which only one degree of freedom is affected. (b) The degree of non-separability in both scenarios varies identically with perturbation strength (SR). Nature Photonics 13, 397–402 (2017)
(a) Shows the intensity of a twin beam of photon pairs onto a SPAD camera sensor. From many intensity measurement, one reconstructs the spatial conditional intensity distribution of a photon from a pair, given that it’s partner was previously measured at (b) A or (c) B. npj Quantum Information 6, 94 (2020)
Professor Bienvenu Ndagano holds the Quebec’s Ministry of Economy and Innovation Chair in Quantum Photonics (2023-2026).
Originally from Bukavu in the Democratic Republic of Congo, Bienvenu Ndagano holds a doctorate (2018) in physics from the University of the Witwatersrand in South Africa. He worked as a postdoctoral researcher at the University of Glasgow from 2018 to 2021, before joining the Fraunhofer Center for Applied Photonics, still in Glasgow from 2021 to 2023. He takes up his post as Associate Professor at the Center for Energy Materials Telecommunications at the National Institute for Scientific Research in Varennes in 2023
Research project in progress or completed
- LIDAR-based quantum imaging
- Non-linear conversion of entanglement in high dimensions
- Non-linear quantum imaging
- High-dimensional entangled state engineering in optical waveguides
In addition to the above list, other research opportunities can be discussed.
Scientific activities
- CRSNG Discovery grant, 2023-2028
- Alliance Consortium grant, 2023-2028
- Photonique Quantique Québec grant, 2023-2025
- MEI Chair in Quantum Photonics, 2023-2026
Collaborations
- Professors Roberto Morandotti, José Azaña, Centre Énergie Matériaux Télécommunications at INRS
- Professors Benjamin Sussman, Ebrahim Karimi and Robert Boyd, University of Ottawa
- Professor Daniele Faccio, University of Glasgow
- Professor Andrew Forbes, University of the Witwatersrand
Publications
- Defienne, P. Cameron, B. Ndagano, A. Lyons, M. Reichert, J. Zhao, E. Charbon, J.W. Fleischer and D. Faccio, “Pixel super-resolution using spatially entangled photon pairs”, Nature Communications 13, 3566 (2022)
- Ndagano, H. Defienne, D. Branford, Y.D. Shah, A. Lyons, N. Westerberg, E.M. Gauger and D. Faccio, “Quantum microscopy based on Hong–Ou–Mandel interference”, Nature Photonics 16, 384-389 (2022)
- Defienne, B. Ndagano, A. Lyons, D. Faccio, “Polarization entanglement-enabled quantum holography”, Nature Physics 17, 591 (2021)
- Ndagano, H. Defienne, A. Lyons, I. Starshynov, F. Villa, S. Tisa and D. Faccio, “Imaging and certifying high-dimensional entanglement with a single-photon avalanche diode camera”, npj Quantum Information 6, 94 (2020)
- Otte, I. Nape, C. Rosales-Guzmán, C. Denz, A. Forbes and B. Ndagano, “High-dimensional cryptography with spatial modes of light: tutorial”, Journal of the Optical Society of America B 37, A309 (2020)
- Ndagano and A. Forbes, “Entanglement distillation by Hong-Ou-Mandel interference with orbital angular momentum states”. APL Photonics 4, 016103 (2019)
- Forbes, A. Aiello, and B. Ndagano, “Classically Entangled Light”, Progress in Optics 64, 99 (2019)
- Rosales-Guzmán, B. Ndagano and A. Forbes, “A review of complex vector light fields and their applications”, Journal of Optics 20, 123001 (2018)
- P. J. Lavery, M. M. Abadi, R. Bauer, G. Brambilla, L. Cheng, M. A. Cox, A. Dudley, A. D. Ellis, N. K. Fontaine, A. E. Kelly, C. Marquardt, S. Matlhane, B. Ndagano, F. Petruccione, R. Slavík, F. Romanato, C. Rosales-Guzmán, F. S. Roux, K. Roux, J. Wang and A. Forbes, “Tackling Africa’s digital divide”, Nature Photonics 12, 249-252 (2018)
- Otte, C. Rosales-Guzmán, B. Ndagano, C. Denz and A. Forbes, “Entanglement beating in free space through spin-orbit coupling”, Light: Science & Applications 7, 18009 (2018)
- Ndagano and A. Forbes, “Characterization and mitigation of information loss in a six-state quantum-key-distribution protocol with spatial modes of light through turbulence”, Physical Review A 98, 062330 (2018)
- Ndagano, B. Perez-Garcia, F. S. Roux, M. McLaren, C. Rosales-Guzmán, Y. Zhang, O. Mouane, R. I. Hernandez-Aranda, T. Konrad and A. Forbes, “Characterizing quantum channels with non-separable states of classical light”, Nature Physics 13, 397 (2017)
- Ndagano, I. Nape, B. Perez-Garcia, S. Scholes, R. I. Hernandez-Aranda, T. Konrad, M. P. J. Lavery and A. Forbes, “A deterministic detector for vector vortex states”, Scientific Reports 7, 19882 (2017)
- Ndagano, I. Nape, M. A. Cox, C. Rosales-Guzmán and A. Forbes, “Creation and characterization of vector vortex modes for classical and quantum communication”, Journal of Lightwave Technology 36, 292 (2017)
- Toninelli, B. Ndagano, A. Valles, B. Sephton, I. Nape, A. Ambrosio, F. Capasso, M. J. Padgett and A. Forbes, “Concepts in quantum state tomography and classical implementation with intense light: a tutorial”, Advances in Optics and Photonics 11, 67 (2017)
- Ndagano, N. Mphuthi, G. Milione and A. Forbes, “Comparing mode-crosstalk and mode-dependent loss of laterally displaced orbital angular momentum and Hermite–Gaussian modes for free-space optical communication”, Optics Letters 42, 4175 (2017)
- Nape, B. Ndagano and A Forbes, “Erasing the orbital angular momentum information of a photon”, Physical Review A 95, 053859 (2017)
- Ndagano, H. Sroor, M. McLaren, C. Rosales-Guzmán and A. Forbes, “Beam quality measure for vector beams”, Optics Letters 41, 3407 (2016)
- Trichili, C. Rosales-Guzmán, A. Dudley, B. Ndagano, A. Ben-Salem, M. Zghal and A. Forbes, “Optical communication beyond orbital angular momentum”, Scientific Reports 6, 27674 (2016)
- Brüning, B. Ndagano, M. McLaren, S. Schröter, J. Kobelke, M. Duparré and A. Forbes, “Data transmission with twisted light through a free-space to fiber optical communication link”, Journal of Optics 18, 03LT01 (2016)
- Ndagano, R. Brüning, M. McLaren, M. Duparré and A. Forbes, “Fiber propagation of vector modes”, Optics Express 23, 17330 (2015)