[1] Hadfield R H. Single-photon detectors for optical quantum information applications[J]. Nature Photonics, 3, 696-705(2009).

[2] Courde C, Torre J M, Samain E et al. Lunar laser ranging in infrared at the Grasse laser station[J]. Astronomy & Astrophysics, 602, A90(2017).

[3] Xia H Y, Shentu G L, Shangguan M et al. Long-range micro-pulse aerosol lidar at 1.5 μm with an upconversion single-photon detector[J]. Optics Letters, 40, 1579-1582(2015).

[4] Gol’tsman G N, Okunev O, Chulkova G et al. Picosecond superconducting single-photon optical detector[J]. Applied Physics Letters, 79, 705-707(2001).

[5] Huo X P, Yang D Z, Yu S L et al. Research on status and development of single photon detector[J]. Laser & Infrared, 53, 3-11(2023).

[6] Ware M, Migdall A. Single-photon detector characterization using correlated photons: the March from feasibility to metrology[J]. Journal of Modern Optics, 51, 1549-1557(2004).

[7] Gerrits T, Migdall A, Bienfang J C et al. Calibration of free-space and fiber-coupled single-photon detectors[J]. Metrologia, 57, 015002(2020).

[8] Degnan J J. Photon-counting multikilohertz microlaser altimeters for airborne and spaceborne topographic measurements[J]. Journal of Geodynamics, 34, 503-549(2002).

[9] Brida G, Castelletto S, Degiovanni I P et al. Quantum efficiency and dead time of single-photon counting photodiodes: a comparison between two measurement techniques[J]. Metrologia, 37, 625-628(2000).

[10] Acerbi F, Tosi A, Dalla M A et al. Experimental characterization of afterpulsing and timing jitter of InGaAs/InP SPAD[J]. Proceedings of SPIE, 7934, 79340L(2011).

[11] Theocharous E, Cheung J, Chunnilall C. Characterisation of photon counting systems at NPL[J]. Proceedings of SPIE, 7681, 768105(2010).

[12] Pawlikowska A M, Halimi A, Lamb R A et al. Single-photon three-dimensional imaging at up to 10 kilometers range[J]. Optics Express, 25, 11919-11931(2017).

[13] Hu Y B, Li J J, Gao D Y et al. Accuracy analysis for coincidence measurement of entangled photons calibration[J]. Acta Photonica Sinica, 48, 0428002(2019).

[14] Shi X S, Liu C M, Zhao K et al. Measurement system for quantum efficiency of the single photon detector based on correlated photons[J]. Acta Photonica Sinica, 46, 0304001(2017).

[15] Xia H Y, Shangguan M J, Wang C et al. Micro-pulse upconversion Doppler lidar for wind and visibility detection in the atmospheric boundary layer[J]. Optics Letters, 41, 5218-5221(2016).

[16] Wang X H, Wang H, Ma L et al. Topotactic fabrication of transition metal dichalcogenide superconducting nanocircuits[J]. Nature Communications, 14, 4282(2023).

[17] Mao S, Wang A, Yi Y et al. Polarization Raman lidar for atmospheric correction during remote sensing satellite calibration: instrument and test measurements[J]. Optics Express, 30, 11986-12007(2022).

[18] Peng X, Zhao X Y, Li L J et al. First-photon imaging via a hybrid penalty[J]. Photonics Research, 8, 325-330(2020).

[19] Ni X X, Hu K. Multi-pulse train cross-correlation method in remote laser ranging[J]. Acta Optica Sinica, 32, 1112005(2012).

[20] Han X, Zhou C. Classification and features of atmospheric lidars: a review[J]. Journal of Nanjing University (Natural Science), 59, 900-913(2023).

[21] Markus T, Neumann T, Martino A et al. The ice, cloud, and land elevation satellite-2 (ICESat-2): science requirements, concept, and implementation[J]. Remote Sensing of Environment, 190, 260-273(2017).

[22] Zhang H Y, Zhao X Y, Zhang Y C et al. Review of advances in single-photon LiDAR[J]. Chinese Journal of Lasers, 49, 1910003(2022).

[23] Liu W T, Nie Z W, Sun S. Invited paper: current state and trends of quantum radar technology[J]. National Defense Technology, 44, 5-22(2023).

[24] Liu C M, Zhang P J, Lin Y J et al. Research progress on calibration technology of single photon detectors[J]. Journal of Astronautic Metrology and Measurement, 43, 34-39(2023).

[25] Hallensleben S, Townsend P D. Enhanced photomultiplier sensitivity in spectroscopy systems[J]. Optics Letters, 25, 1511-1513(2000).

[26] Wu Q L, Liu Y, Chen W et al. Advanced single-photon detector technologies[J]. Progress in Physics, 30, 296-306(2010).

[27] Ren M, Gu X R, Liang Y et al. Laser ranging at 1550 nm with 1-GHz sine-wave gated InGaAs/InP APD single-photon detector[J]. Optics Express, 19, 13497-13502(2011).

[28] Gu M, Kang L, Zhang L B et al. High detection efficiency and rate superconducting nanowire single-photon detector with a composite optical structure[J]. Proceedings of SPIE, 9357, 93571K(2015).

[29] Sommer A H[M]. Photoemissive materials: preparation, properties, and uses, 15031221(1979).

[30] Zhao W J. Developments in technology of photomultipliers[J]. Optoelectronic Technology, 31, 145-148(2011).

[31] Laforce F. Low noise optical receiver using Si APD[J]. Proceedings of SPIE, 7212, 721210(2009).

[32] Wang Z, Tian N, Yang X et al. Overview of imaging technology based on single photon avalanche diode[J]. Integrated Circuits and Embedded Systems, 24, 10-25, 2(2024).

[33] Kerman A J, Dauler E A, Keicher W E et al. Kinetic-in-ductance-limited reset time of superconducting nanowire photon counters[J]. Applied Physics Letters, 88, 111116(2006).

[34] Yang J K W, Kerman A J, Dauler E A et al. Modeling the electrical and thermal response of superconducting nanowire single-photon detectors[J]. IEEE Transactions on Applied Superconductivity, 17, 581-585(2007).

[35] Hu X L, Hu N, Zou K et al. Twenty-year research and development of SNSPDs: review and prospects[J]. Laser Technology, 46, 1-37(2022).

[36] Papageorgas P G, Winter H, Albrecht H et al. A multichannel photon counting system for gas analysis with Raman-scattering technique[J]. IEEE Transactions on Instrumentation and Measurement, 48, 1166-1177(1999).

[37] Akulinichev V V, Kurnin I V, Kurochkina E G. Eyesafe lidar by the solid state Er: glass laser[J]. Proceedings of SPIE, 5478, 291-297(2004).

[38] Albota M A, Wong F N C. Efficient single-photon counting at 1.55 µm by means of frequency upconversion[J]. Optics Letters, 29, 1449-1451(2004).

[39] Shentu G L, Pelc J S, Wang X D et al. Ultralow noise up-conversion detector and spectrometer for the telecom band[J]. Optics Express, 21, 13986-13991(2013).

[40] Ma F, Zheng M Y, Yao Q et al. 1.064-μm-band up-conversion single-photon detector[C], JTh2A.12(2018).

[41] Demur R, Garioud R, Grisard A et al. Near-infrared to visible upconversion imaging using a broadband pump laser[J]. Optics Express, 26, 13252-13263(2018).

[42] Høgstedt L, Fix A, Wirth M et al. Upconversion-based lidar measurements of atmospheric CO2[J]. Optics Express, 24, 5152-5161(2016).

[43] Guo J J, Fei X Y, Ge P et al. High-resolution three-dimensional imaging based on all-fiber photon-counting Lidar system[J]. Infrared and Laser Engineering, 50, 20210162(2021).

[44] Zhang X Y, Wang F X, Guo Y et al. Research on linear array scanning lidar and photon signal processing technology based on InGaAs single-photon detector[J]. Infrared and Laser Engineering, 52, 20220474(2023).

[45] Ren X M, Connolly P W R, Halimi A et al. High-resolution depth profiling using a range-gated CMOS SPAD quanta image sensor[J]. Optics Express, 26, 5541-5557(2018).

[46] Ren L Q, Yin X C, He B. Development prospect of quantum radar in meteorological detection[J]. Changjiang Information & Communications, 36, 13-14, 18(2023).

[47] Papageorgas P G, Maroulis D, Winter H et al. Multichannel Raman gas analyzer: the data acquisition and control system. Measurement improvement with blue laser light[J]. IEEE Transactions on Instrumentation and Measurement, 53, 58-66(2004).

[48] Tsupryk A, Tovkach I, Gavrilov D et al. Ultra sensitive sensor with enhanced dynamic range for high speed detection of multi-color fluorescence radiation[J]. Biosensors and Bioelectronics, 23, 1512-1518(2008).

[49] Sakaizawa D, Nagasawa C, Nagai T et al. Development of a 1.6 μm differential absorption lidar with a quasi-phase-matching optical parametric oscillator and photon-counting detector for the vertical CO2 profile[J]. Applied Optics, 48, 748-757(2009).

[50] Albota M A, Robinson B S. Photon-counting 1.55 μm optical communications with pulse-position modulation and a multimode upconversion single-photon receiver[J]. Optics Letters, 35, 2627-2629(2010).

[51] Wang Y G, Zhang Y X, Wang J Y et al. Degree of polarization for single-photon beam in a turbulent atmosphere[J]. Optics Communications, 284, 3221-3226(2011).

[52] Riris H, Rodriguez M, Allan G R et al. Pulsed airborne lidar measurements of atmospheric optical depth using the Oxygen A-band at 765 nm[J]. Applied Optics, 52, 6369-6382(2013).

[53] Meng L C, Fix A, Wirth M et al. Upconversion detector for range-resolved DIAL measurement of atmospheric CH4[J]. Optics Express, 26, 3850-3860(2018).

[54] Barton-Grimley R A, Stillwell R A, Thayer J P. High resolution photon time-tagging lidar for atmospheric point cloud generation[J]. Optics Express, 26, 26030-26044(2018).

[55] Taylor G G, Morozov D, Gemmell N R et al. Photon counting LIDAR at 2.3 µm wavelength with superconducting nanowires[J]. Optics Express, 27, 38147-38158(2019).

[56] Yang F, Sua Y M, Louridas A et al. A time-gated, time-correlated single-photon-counting lidar to observe atmospheric clouds at submeter resolution[J]. Remote Sensing, 15, 1500(2023).

[57] Yang F, Kostinski A B, Zhu Z E et al. A single-photon lidar observes atmospheric clouds at decimeter scales: resolving droplet activation within cloud base[J]. NPJ Climate and Atmospheric Science, 7, 92-100(2024).

[58] Boretti A. A perspective on single-photon LiDAR systems[J]. Microwave and Optical Technology Letters, 66, e33918(2024).

[59] Wang C, Xia H Y, Shangguan M J et al. 1.5 μm polarization coherent lidar incorporating time-division multiplexing[J]. Optics Express, 25, 20663-20674(2017).

[60] Shangguan M J, Xia H Y, Wang C et al. Dual-frequency Doppler lidar for wind detection with a superconducting nanowire single-photon detector[J]. Optics Letters, 42, 3541-3544(2017).

[61] Qiu J W, Xia H Y, Shangguan M J et al. Micro-pulse polarization lidar at 1.5 μm using a single superconducting nanowire single-photon detector[J]. Optics Letters, 42, 4454-4457(2017).

[62] Shang X, Xia H Y, Dou X K et al. Adaptive inversion algorithm for 1.5 μm visibility lidar incorporating in situ Angstrom wavelength exponent[J]. Optics Communications, 418, 129-134(2018).

[63] Li M Y, Wu Y B, Yuan J L et al. Stratospheric aerosol lidar with a 300 µm diameter superconducting nanowire single-photon detector at 1064 nm[J]. Optics Express, 31, 2768-2779(2023).

[64] Zhu J, Chen Y J, Zhang L B et al. Demonstration of measuring sea fog with an SNSPD-based Lidar system[J]. Scientific Reports, 7, 15113(2017).

[65] Guan Y Q, Li H C, Xue L et al. Lidar with superconducting nanowire single-photon detectors: recent advances and developments[J]. Optics and Lasers in Engineering, 156, 107102(2022).

[66] Zhang B, Chen Q, Guan Y Q et al. Research progress of photon response mechanism of superconducting nanowire single photon detector[J]. Acta Physica Sinica, 70, 198501(2021).

[67] Wang X Y, Zhao N, Chen N et al. Effects of atmospheric turbulence on the single-photon receiving efficiency and the performance of quantum channel with the modified approximate elliptic-beam model assumption[J]. Quantum Information Processing, 17, 14(2017).

[68] Wu C, Xing W G, Feng Z J et al. Moving target tracking in marine aerosol environment with single photon lidar system[J]. Optics and Lasers in Engineering, 127, 105967(2020).

[69] Zeng J Z. Research on elevation variation of glaciers on the Qinghai-Tibet Plateau combined with single photon laser and digital elevation model[D](2023).

[70] Shentu G L, Wang C, Shang X et al. The development of particle quantum lidar and its application in environmental monitoring[J]. Information and Communications Technology and Policy, 52-59(2022).

[71] Chen Q Y, Mao S, Yin Z P et al. Compact and efficient 1064 nm up-conversion atmospheric lidar[J]. Optics Express, 31, 23931-23943(2023).

[72] Yin Z P, Wang L L, He Y et al. Understanding the roles of aerosols and clouds in environment, meteorology and climate with advanced lidar remote sensing techniques[J]. Remote Sensing, 16, 593-597(2024).

[73] Shangguan M J, Liao Z Y, Guo Y R et al. Sensing the profile of particulate beam attenuation coefficient through a single-photon oceanic Raman lidar[J]. Optics Express, 31, 25398-25414(2023).

[74] Chen J F, Xie C B, Ji J. Development of a compact space-borne Lidar for atmospheric aerosol and cloud detection[J]. Atmospheric Environment, 309, 119915(2023).

[75] Xu C Y, Cao J, Yang F et al. Advances in long-range low-slow-small target detection technology (invited)[J]. Laser & Optoelectronics Progress, 61, 2011004(2024).

[76] Zhang C Y, Mo D F, Xu H Y et al. Progress in packaging technology of InGaAs avalanche photodiode detectors[J]. Laser & Optoelectronics Progress, 61, 0900009(2024).

[77] He R, Zhu L, Dong J F et al. Modeling and simulation of LiDAR based on single-photon avalanche diode[J]. Laser & Optoelectronics Progress, 61, 1028003(2024).