WI-SNSPD: enabling quantum through scalable and cost effective detector solutions

Waveguide-Integrated Superconducting Nanowire Single-Photon Detectors (WI-SNSPDs) represent a transformative advancement in single-photon detection technology, combining the exceptional sensitivity of traditional SNSPDs with the scalability and integration potential of Photonic Integrated Circuits (PICs). This integration eliminates the need for optical cavities, significantly broadens spectral bandwidth, and reduces optical losses, enabling compact, high-throughput systems. SNSPDs achieve peak system detection efficiencies exceeding 99%, timing jitter as low as 3 ps, and ultra-low dark count rates below 0.1 mHz. In combination with photonic integration these features make WI-SNSPDs ideal for time-sensitive quantum applications such as Quantum Key Distribution (QKD) and photonic quantum computing. Key challenge for a high System Detection Efficiency (SDE) of WI-SNSPDs is the coupling of light to the photonic circuit. Recent advancements in Direct Laser Written (DLW) spot size converters show very high potential, achieving coupling efficiencies exceeding 83% (up to 95% in simulation) with exceptional reproducibility potentially enabling very high System Detection Efficiencies (SDE). WI-SNSPDs also support transformative applications in imaging and microscopy, enabling high-resolution, non-invasive deep-tissue imaging with minimal optical noise due to their potential for multi-mode and extreme broadband sensitivity. Pixel Photonics’ industrial roadmap focuses on the scalability of WI-SNSPDs through wafer-scale production and seamless integration with PICs, supporting the development of co-integrated systems that combine detectors with photonic quantum processors. This integration eliminates fiber-chip links, paving the way for compact and scalable quantum computing architectures. Additionally, WI-SNSPDs facilitate the creation of quantum links in large-scale quantum networks by enabling efficient photon entanglement distribution. These advancements position WI-SNSPDs as a cornerstone technology for next-generation quantum computing, secure communication networks, advanced imaging, and hybrid photonic systems, driving innovation across research and industry.