TY - JOUR
T1 - Cascaded Metasurface Interferometer for Multipath Interference with Classical and Quantum Light
AU - Aschwanden, Rebecca
AU - Claro-Rodríguez, Nicolás
AU - Zhao, Ruizhe
AU - Kallert, Patricia
AU - Krieger, Tobias
AU - Buchinger, Quirin
AU - Covre da Silva, Saimon F.
AU - Stroj, Sandra
AU - Rota, Michele
AU - Höfling, Sven
AU - Huber-Loyola, Tobias
AU - Rastelli, Armando
AU - Trotta, Rinaldo
AU - Huang, Lingling
AU - Bartley, Tim
AU - Jöns, Klaus D.
AU - Zentgraf, Thomas
N1 - Publisher Copyright:
© 2026 American Chemical Society
PY - 2026/5/6
Y1 - 2026/5/6
N2 - Beamsplitters represent fundamental components in both classical and quantum optical systems, enabling the distribution of light, as well as the generation of interference, superposition, and entanglement. However, optical networks constructed from conventional bulk 2 × 2-beamsplitters encounter inherent scalability issues, as the number of required beamsplitters scales quadratically with the number of optical modes for a fully connected network. Metasurfaces offer a promising route to overcome these constraints. By manipulating light at the wavelength scale, compact optical components with advanced functionalities can be constructed, which address several modes simultaneously. In this work, we design and experimentally utilize a metasurface as a multiport beamsplitter. Furthermore, we realized a multimode interferometer composed of two cascaded metasurfaces. We characterize the individual and cascaded metasurfaces by using classical light, showing controllable splitting ratios through tunable phase relations. We then expand the approach to quantum light, employing single photons to demonstrate second- and third-order photon correlations as well as single photon interference across multiple spatial paths. These results establish metasurface-based multiport beamsplitters as a scalable and reconfigurable platform bridging classical and quantum photonics.
AB - Beamsplitters represent fundamental components in both classical and quantum optical systems, enabling the distribution of light, as well as the generation of interference, superposition, and entanglement. However, optical networks constructed from conventional bulk 2 × 2-beamsplitters encounter inherent scalability issues, as the number of required beamsplitters scales quadratically with the number of optical modes for a fully connected network. Metasurfaces offer a promising route to overcome these constraints. By manipulating light at the wavelength scale, compact optical components with advanced functionalities can be constructed, which address several modes simultaneously. In this work, we design and experimentally utilize a metasurface as a multiport beamsplitter. Furthermore, we realized a multimode interferometer composed of two cascaded metasurfaces. We characterize the individual and cascaded metasurfaces by using classical light, showing controllable splitting ratios through tunable phase relations. We then expand the approach to quantum light, employing single photons to demonstrate second- and third-order photon correlations as well as single photon interference across multiple spatial paths. These results establish metasurface-based multiport beamsplitters as a scalable and reconfigurable platform bridging classical and quantum photonics.
KW - beamsplitter
KW - interferometer
KW - metasurface
KW - nanophotonics
KW - quantum network
KW - single photons
UR - https://www.scopus.com/pages/publications/105037876188
U2 - 10.1021/acsphotonics.6c00096
DO - 10.1021/acsphotonics.6c00096
M3 - Article
AN - SCOPUS:105037876188
SN - 2330-4022
VL - 13
SP - 2579
EP - 2585
JO - ACS Photonics
JF - ACS Photonics
IS - 9
ER -