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Laser & Optoelectronics Progress, Volume. 58, Issue 10, 1011005(2021)

Recent Progress of Imaging Applications Based on Superconducting Nanowire Single-Photon Detectors

Hui Zhou1,2、**, Chengjun Zhang1,2, Chaolin Lü1,2, Xingyu Zhang1,2, Hao Li1,2,3, Lixing You1,2,3、*, and Zhen Wang1,2,3
Author Affiliations
  • 1State Key Laboratory of Functional Materials for Informatics, Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences, Shanghai 200050, China
  • 2CAS Center for Excellence in Superconducting Electronics, Shanghai 200050, China
  • 3Center of Materials Science and Optoelectronics Engineering, University of Chinese Academy of Sciences, Beijing 100049, China
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    Figures & Tables(16)
    SEM images. (a) SEM image of SNSPD with 15 μm diameter photosensitive surface; (b) SEM image of nanowire after partial magnification

    Fig. 1. SEM images. (a) SEM image of SNSPD with 15 μm diameter photosensitive surface; (b) SEM image of nanowire after partial magnification

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    Schematics of SNSPD operation principle based on hotspot model [12]

    Fig. 2. Schematics of SNSPD operation principle based on hotspot model [12]

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    SDE performance comparison of different SPDs[5,14,25,30-36]

    Fig. 3. SDE performance comparison of different SPDs[5,14,25,30-36]

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    TCSPC technology. (a) Schematic diagram of TCSPC technology [41]; (b) schematic diagram of TCSPC-based Lidar

    Fig. 4. TCSPC technology. (a) Schematic diagram of TCSPC technology [41]; (b) schematic diagram of TCSPC-based Lidar

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    SNSPD ranging system. (a) Scanning imaging system based on SNSPD; (b) 1 km distance imaging results at different viewpoints of the scenes[43]

    Fig. 5. SNSPD ranging system. (a) Scanning imaging system based on SNSPD; (b) 1 km distance imaging results at different viewpoints of the scenes[43]

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    Laser ranging based on SNSPD. (a) Schematics of the LARES satellite ranging system 3000 km away based on SNSPD; (b) ranging result[15]

    Fig. 6. Laser ranging based on SNSPD. (a) Schematics of the LARES satellite ranging system 3000 km away based on SNSPD; (b) ranging result[15]

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    Few-photon scanning imaging with sub-millimeter depth resolution. (a) Reconstructed profile of a small key achieved by detecting and time-tagging reflected photons; (b) dwell time at each position of the scan was fixed to 20 ms meaning that the number of detected photons was different at each location; (c) distribution of the detected number of photons in the pixels of the scan[28]

    Fig. 7. Few-photon scanning imaging with sub-millimeter depth resolution. (a) Reconstructed profile of a small key achieved by detecting and time-tagging reflected photons; (b) dwell time at each position of the scan was fixed to 20 ms meaning that the number of detected photons was different at each location; (c) distribution of the detected number of photons in the pixels of the scan[28]

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    Bioluminescence lifetime imaging. (a) Schematic diagram of confocal fluorescence lifetime imaging microscope based on SNSPD; (b) NIR-II confocal fluorescence lifetime imaging of rat glioma cells[50]

    Fig. 8. Bioluminescence lifetime imaging. (a) Schematic diagram of confocal fluorescence lifetime imaging microscope based on SNSPD; (b) NIR-II confocal fluorescence lifetime imaging of rat glioma cells[50]

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    Experimental results. (a) Multi-pixel SNSPD schematic diagram based on double-ended readout technology and 590 pixel single-photon imaging demonstration experiment[51]; (b) multi-pixel SNSPD camera and 16 pixel×16 pixel 3D single-photon image reconstruction process based on dual-end readout technology[52]

    Fig. 9. Experimental results. (a) Multi-pixel SNSPD schematic diagram based on double-ended readout technology and 590 pixel single-photon imaging demonstration experiment[51]; (b) multi-pixel SNSPD camera and 16 pixel×16 pixel 3D single-photon image reconstruction process based on dual-end readout technology[52]

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    Experimental results. (a) Schematic of thousand-pixel array SNSPD read by row-column array; (b) optical micrograph of the array; (c) chip-scale layout of the array; (d)(e) log-scale count rate across the array under illumination with a focused laser beam; (f) persistence images when the laser spot sweeps across the array[54]

    Fig. 10. Experimental results. (a) Schematic of thousand-pixel array SNSPD read by row-column array; (b) optical micrograph of the array; (c) chip-scale layout of the array; (d)(e) log-scale count rate across the array under illumination with a focused laser beam; (f) persistence images when the laser spot sweeps across the array[54]

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    Schematic of ghost imaging[59]

    Fig. 11. Schematic of ghost imaging[59]

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    Schematic diagram of single-pixel imaging [60]

    Fig. 12. Schematic diagram of single-pixel imaging [60]

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    Experimental results. (a) Schematic diagram of compressed sensing imaging experiment based on SNSPD; (b) imaging results[65]

    Fig. 13. Experimental results. (a) Schematic diagram of compressed sensing imaging experiment based on SNSPD; (b) imaging results[65]

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    • Table 1. Typical parameters of commonly used SPDs

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      Table 1. Typical parameters of commonly used SPDs

      Detector typeOperation temperature/KEffective area/mmWavelengthrange/μmSystem detection efficiency @ wavelength /(%@μm)Dark count rate /HzTiming jitter/psDead time/nsMax. count rate /MHz
      PMT[2]300Φ50.2--150@0.51003005010
      IR-PMT [3]200Φ1.61--1.73@1.52000003005010
      Si-SPAD [4]250Φ0.05--30.5--1.060@650;80@0.8;10@1.020005010010
      InGaAs--SPAD [5]200Φ0.050.9--1.725--55@1.5200015010--10010--500
      SNSPD [6]1--4Φ0.015--0.10.2--9.9>80@0.2--1.5100505020--500
      TES[7]0.10.02×0.02γ-ray-millimeter wave>95@0.85--1.50103--10510000.1--1

    • Table 2. Experimental results of laser ranging under different echo intensities[71]

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      Table 2. Experimental results of laser ranging under different echo intensities[71]

      Attenuation factor/dBEcho photon number/HzSPADSNSPDSPADSNSPD
      Average range ofdetection /kmExperimental detectionprobability /%
      1012010.5210.518095
      304210. 5610.533575
      602011.2510.522060
      120812, 4710.520.2935

    • Table 3. Performance comparison of mid-infrared molecular spectrum detection system between SNSPD and InSb detector[78]

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      Table 3. Performance comparison of mid-infrared molecular spectrum detection system between SNSPD and InSb detector[78]

      DetectorResponse
      time /ns      		aNEP /(pW/Hz1/2)Wavelength
      range /μm      		Temperature
      / K      		Detector
      size /μm
      WSi SNSPD<10.0052-7b0.316×16
      InSb>10000.71-5.5c77dia.1000
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    Hui Zhou, Chengjun Zhang, Chaolin Lü, Xingyu Zhang, Hao Li, Lixing You, Zhen Wang. Recent Progress of Imaging Applications Based on Superconducting Nanowire Single-Photon Detectors[J]. Laser & Optoelectronics Progress, 2021, 58(10): 1011005

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    Paper Information

    Category: Imaging Systems

    Received: Feb. 1, 2021

    Accepted: Mar. 5, 2021

    Published Online: May. 28, 2021

    The Author Email: Hui Zhou (zhouhui@mial.sim.ac.cn), Lixing You (lxyou@mail.sim.ac.cn)

    DOI:10.3788/LOP202158.1011005

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology