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NbN Superconducting Nanowire Single-Photon Detector With 90.5% Saturated System Detection Efficiency and 14.7 ps System Jitter at 1550 nm Wavelength

Xingyu Zhang, Weijun Zhang, Hui Zhou, Xiaofu Zhang, Lixing You, Hao Li, Dong-Hui Fan, Yiming Pan, Huiqin Yu, Lingyun Li, Zhen Wang

2022IEEE Journal of Selected Topics in Quantum Electronics24 citationsDOI

Abstract

Superconducting nanowire single-photon detectors (SNSPDs) play a pivotal role in infrared single-photon-detection applications owing to their free-running mode, near-unity detection efficiency, and excellent time resolution. However, conventional niobium nitride- (NbN) SNSPDs often have a trade-off between optimal detection efficiency and time resolution. We herein demonstrate NbN SNSPDs in the combination of high efficiency and time resolution by using the helium-ion-irradiated film of 10 nm and a homemade cryogenic amplifier to improve the signal-to-noise ratio. The proposed 18-μm-diameter device operated at 850 mK shows a saturated system detection efficiency of ∼90.5% at 1550 nm wavelength with a dark count rate below 50 counts per second (cps), and minimum system timing jitter of ∼14.7 ps. Meanwhile, the recovery time is 21.2 ns owing to its lower kinetic inductance. The time-of-flight light detection and ranging with this device was further carried out indoors, which demonstrates a submillimeter (<0.5 mm) depth resolution, as well as good depth and intensity reconstruction of a low-signature object even under the dwell time of 0.5 ms. It indicates that our device has a great advantage and potential in high-time-resolution and weak-signal-detection applications, such as real-time imaging, fluorescence lifetime detection, and remote laser sensing.

Topics & Concepts

JitterMaterials scienceDetectorOptoelectronicsPhoton countingOpticsKinetic inductancePhotonicsNiobium nitridePhysicsNitrideInductanceVoltageNanotechnologyQuantum mechanicsElectronic engineeringEngineeringLayer (electronics)Advanced Optical Sensing TechnologiesAdvanced Fiber Laser TechnologiesAdvanced Fluorescence Microscopy Techniques