| A review of complex vector light fields and their applications C Rosales-Guzmán, B Ndagano, A Forbes Journal of Optics 20 (12), 123001, 2018 | 422 | 2018 |
| Creation and detection of vector vortex modes for classical and quantum communication B Ndagano, I Nape, MA Cox, C Rosales-Guzman, A Forbes Journal of Lightwave Technology 36 (2), 292-301, 2017 | 298 | 2017 |
| Characterizing quantum channels with non-separable states of classical light B Ndagano, B Perez-Garcia, FS Roux, M McLaren, C Rosales-Guzman, ... Nature Physics 13 (4), 397-402, 2017 | 279 | 2017 |
| Optical communication beyond orbital angular momentum A Trichili, C Rosales-Guzmán, A Dudley, B Ndagano, A Ben Salem, ... Scientific reports 6 (1), 27674, 2016 | 228 | 2016 |
| Concepts in quantum state tomography and classical implementation with intense light: a tutorial E Toninelli, B Ndagano, A Vallés, B Sephton, I Nape, A Ambrosio, ... Advances in Optics and Photonics 11 (1), 67-134, 2019 | 151 | 2019 |
| Beam quality measure for vector beams B Ndagano, H Sroor, M McLaren, C Rosales-Guzmán, A Forbes Optics letters 41 (15), 3407-3410, 2016 | 130 | 2016 |
| Entanglement beating in free space through spin–orbit coupling E Otte, C Rosales-Guzmán, B Ndagano, C Denz, A Forbes Light: Science & Applications 7 (5), 18009-18009, 2018 | 123 | 2018 |
| Fiber propagation of vector modes B Ndagano, R Brüning, M McLaren, M Duparré, A Forbes Optics express 23 (13), 17330-17336, 2015 | 120 | 2015 |
| Polarization entanglement-enabled quantum holography H Defienne, B Ndagano, A Lyons, D Faccio Nature Physics 17 (5), 591-597, 2021 | 119 | 2021 |
| Classically entangled light A Forbes, A Aiello, B Ndagano Progress in Optics 64, 99-153, 2019 | 90 | 2019 |
| Tackling Africa’s digital divide MPJ Lavery, MM Abadi, R Bauer, G Brambilla, L Cheng, MA Cox, ... Nature Photonics 12 (5), 249-252, 2018 | 79 | 2018 |
| A deterministic detector for vector vortex states B Ndagano, I Nape, B Perez-Garcia, S Scholes, RI Hernandez-Aranda, ... Scientific reports 7 (1), 13882, 2017 | 74 | 2017 |
| Quantum microscopy based on Hong–Ou–Mandel interference B Ndagano, H Defienne, D Branford, YD Shah, A Lyons, N Westerberg, ... Nature Photonics 16 (5), 384-389, 2022 | 73 | 2022 |
| Comparing mode-crosstalk and mode-dependent loss of laterally displaced orbital angular momentum and Hermite–Gaussian modes for free-space optical communication B Ndagano, N Mphuthi, G Milione, A Forbes Optics letters 42 (20), 4175-4178, 2017 | 70 | 2017 |
| High-dimensional cryptography with spatial modes of light: tutorial E Otte, I Nape, C Rosales-Guzmán, C Denz, A Forbes, B Ndagano JOSA B 37 (11), A309-A323, 2020 | 60 | 2020 |
| Imaging and certifying high-dimensional entanglement with a single-photon avalanche diode camera B Ndagano, H Defienne, A Lyons, I Starshynov, F Villa, S Tisa, D Faccio npj Quantum Information 6 (1), 94, 2020 | 52 | 2020 |
| Data transmission with twisted light through a free-space to fiber optical communication link R Brüning, B Ndagano, M McLaren, S Schröter, J Kobelke, M Duparré, ... Journal of Optics 18, 03LT01, 2016 | 41 | 2016 |
| Pixel super-resolution with spatially entangled photons H Defienne, P Cameron, B Ndagano, A Lyons, M Reichert, J Zhao, ... Nature communications 13 (1), 3566, 2022 | 38 | 2022 |
| Erasing the orbital angular momentum information of a photon I Nape, B Ndagano, A Forbes Physical Review A 95 (5), 053859, 2017 | 24 | 2017 |
| Characterization and mitigation of information loss in a six-state quantum-key-distribution protocol with spatial modes of light through turbulence B Ndagano, A Forbes Physical Review A 98 (6), 062330, 2018 | 20 | 2018 |
Andrew ForbesUniversity of the Witwatersrand在 wits.ac.za 的电子邮件经过验证
