[1] Bouwmeester D, Ekert A, Zeilinger A[M]. The physics of quantum information(2000).

[2] Villoresi P, Jennewein T, Tamburini F et al. Experimental verification of the feasibility of a quantum channel between space and Earth[J]. New Journal of Physics, 10, 033038(2008).

[3] Cong S, Song Y Y, Shang W W et al. Discussion on navigation and positioning system composed of three quantum satellites[J]. Journal of Navigation and Positioning, 7, 1-9(2019).

[4] Xu H X. Overview of the development of quantum communication networks[J]. Journal of China Academy of Electronics and Information Technology, 9, 259-271(2014).

[5] Valencia A, Scarcelli G, Shih Y. Distant clock synchronization using entangled photon pairs[J]. Applied Physics Letters, 85, 2655-2657(2004).

[6] Ursin R, Jennewein T, Kofler J et al. Space-quest, experiments with quantum entanglement in space[J]. Europhysics News, 40, 26-29(2009).

[7] Zhang S B, Chang Y, Yan L L et al. Quantum communication networks and trust management: a survey[J]. Materials and Continua, 61, 1145-1174(2019).

[8] Peng C Z, Pan J W. Quantum science experimental satellite “Micius”[J]. Bulletin of Chinese Academy of Sciences, 31, 1096-1104(2016).

[9] Ursin R, Tiefenbacher F, Schmitt-Manderbach T et al. Entanglement-based quantum communication over 144 km[J]. Nature Physics, 3, 481-486(2007).

[10] Takesue H, Nam S W, Zhang Q et al. Quantum key distribution over a 40-dB channel loss using superconducting single-photon detectors[J]. Nature Photonics, 1, 343-348(2007).

[11] Liu Y, Chen T Y, Wang J et al. Decoy-state quantum key distribution with polarized photons over 200 km[J]. Optics Express, 18, 8587-8594(2010).

[12] Liu T, Zhu C, Sun C Y et al. Influences of different weather conditions on performance of free-space quantum communication system[J]. Acta Optica Sinica, 40, 0227001(2020).

[13] Zhang X Z, Xu X, Liu B Y. Influence of fog on performance of free-space quantum communication[J]. Acta Optica Sinica, 40, 0727001(2020).

[14] Liu B Y, Zhang X Z, Xu X. Influence of soot agglomerated particles on quantum satellite communication performance[J]. Acta Optica Sinica, 40, 0327001(2020).

[15] Nie M, Shi L, Yang G et al. Influence of thunderstorm cloud on the performance of satellite-to-ground quantum link and parameters simulation[J]. Journal on Communications, 38, 31-38(2017).

[16] Wang G, Shen D, Chen G S et al. Polarization tracking for quantum satellite communications[J]. Proceedings of SPIE, 9085, 90850T(2014).

[17] Gao K, Nie M, Yang G et al. Performance of free-space quantum communication in context of rainfall[J]. Laser & Optoelectronics Progress, 54, 012701(2017).

[18] Nie M, Wang Y, Yang G et al. Optimal mean photon number of decoy state protocol based on chameleon self-adaptive strategy under the background of rainfall[J]. Acta Physica Sinica, 65, 020303(2016).

[19] Marshall J S, Palmer W M K. The distribution of raindrops with size[J]. Journal of Meteorology, 5, 165-166(1948).

[20] Li W M, Ao F L, Yu S Y. Study of forward scattering effections on laser transformation in raindrop[J]. Photon Technology, 237-240(2006).

[21] van de Hulst H C, Twersky V. Light scattering by small particles[J]. Physics Today, 10, 28-30(1957).

[22] Lanzagorta M. Quantum radar[M]. Transl. Beijing: Publishing House of Electronics Industry, 54-59(2013).

[23] Guo J, Zhang H, Wang X F. Attenuation and transmission of laser radiation at 532 nm and 1064 nm through rain[J]. Acta Optica Sinica, 31, 0101004(2011).

[24] Yin H, Han Y[M]. Quantum communication theory and technology, 63-66(2013).

[25] Wen Q Y, Guo F Z, Zhu F C[M]. Design and analysis of quantum secure communication protocol, 213-216(2009).

[26] Gu Y J, Zheng Y Z, Guo G C. Probabilistic teleportation of an arbitrary two-particle state[J]. Chinese Physics Letters, 18, 1543-1545(2001).

[27] Liao Z Y, Al-Amri M, Zubairy M S. Protecting quantum entanglement from amplitude damping[J]. Molecular and Optical Physics, 46, 145501(2013).