Detector-integrated on-chip QKD receiver for GHz clock rates
Beutel F, Gehring H, Wolff M A, Schuck C, Pernice W H P
Research article (journal) | Peer reviewedAbstract
Quantum key distribution (QKD) can greatly benefit from photonic integration, which enables implementing low-loss, alignment-free, and scalable photonic circuitry. At the same time, superconducting nanowire single-photon detectors (SNSPD) are an ideal detector technology for QKD due to their high efficiency, low dark-count rate, and low jitter. We present a QKD receiver chip featuring the full photonic circuitry needed for different time-based protocols, including single-photon detectors. By utilizing waveguide-integrated SNSPDs we achieve low dead times together with low dark-count rates and demonstrate a QKD experiment at 2.6 GHz clock rate, yielding secret-key rates of 2.5 Mbit/s for low channel attenuations of 2.5 dB without detector saturation. Due to the broadband 3D polymer couplers the reciver chip can be operated at a wide wavelength range in the telecom band, thus paving the way for highly parallelized wavelength-division multiplexing implementations.
Details about the publication
Authors from the University of Münster
| Beutel, Fabian | Professorship for Experimental Physics and Physics of Responsive Nanosystems (Prof. Pernice) Center for Soft Nanoscience (SoN) |
| Gehring, Helge | Professorship for Experimental Physics and Physics of Responsive Nanosystems (Prof. Pernice) Center for Soft Nanoscience (SoN) |
| Pernice, Wolfram | Professorship for Experimental Physics and Physics of Responsive Nanosystems (Prof. Pernice) Center for Soft Nanoscience (SoN) |
| Schuck, Carsten | Professorship of Experimental Physics (Prof. Schuck) Center for Soft Nanoscience (SoN) Münster Nanofabrication Facility (MNF) |
| Wolff, Martin Axel | Professorship of Experimental Physics (Prof. Schuck) Center for Soft Nanoscience (SoN) |
Projects the publication originates from
Duration: 01/11/2018 - 28/02/2021 Funded by: Federal Ministry of Research, Technology and Space Type of project: Participation in federally funded joint project | |
Duration: 01/09/2016 - 31/03/2022 Type of project: Own resources project |