[1] Miao E L, Han Z F, Gong S S et al. Background noise of satellite-to-ground quantum key distribution[J]. New Journal of Physics, 7, 215(2005).

[2] Yang R, Li Y X, Meng W et al. Channel characteristics of continuous variable quantum communication system on aviation platform[J]. Acta Optica Sinica, 38, 0927002(2018).

[3] Lukin I P, Rychkov D S, Falits A V et al. A phase screen model for simulating numerically the propagation of a laser beam in rain[J]. Quantum Electronics, 39, 863-868(2009).

[4] Nie M, Ren J, Yang G et al. Influences of PM2.5 atmospheric pollution on the performance of free space quantum communication[J]. Acta Physica Sinica, 64, 150301(2015).

[5] Vasylyev D, Semenov A, Vogel W. Atmospheric quantum channels with weak and strong turbulence[J]. Physical Review Letters, 117, 090501(2016).

[6] Vasylyev D, Semenov A A, Vogel W et al. Free-space quantum links under diverse weather conditions[J]. Physical Review A, 96, 043856(2017).

[7] Wang S Y, Huang P, Wang T et al. Atmospheric effects on continuous-variable quantum key distribution[J]. New Journal of Physics, 20, 083037(2018).

[8] Singal P, Rai S, Punia R et al. Comparison of different transmitters using 1550 nm and 10000 nm in FSO communication systems[J]. International Journal of Computer Science and Information Technology, 7, 107-113(2015).

[9] Liu T, Zhang J Z, Zhu C et al. Investigation of the wavelength selection for the free space optical communication system. [C]//2018 Asia Communications and Photonics Conference (ACP), October 26-29, 2018, Hangzhou, China. New York: IEEE, 18382444(2018).

[10] Gariano J, Djordjevic I, Liu T. Optimal wavelength selection for entangled quantum key distribution. [C]//2017 IEEE Photonics Conference (IPC), October 1-5, 2017, Orlando, FL, USA. New York: IEEE, 721-722(2017).

[11] Xu B J, Tang C M, Chen H et al. Improving the maximum transmission distance of continuous variable no-switching QKD protocol[J]. Acta Physica Sinica, 62, 070301(2013).

[12] García-Patrón R, Cerf N J. Unconditional optimality of Gaussian attacks against continuous-variable quantum key distribution[J]. Physical Review Letters, 97, 190503(2006).

[13] Fossier S, Diamanti E, Debuisschert T et al. Improvement of continuous-variable quantum key distribution systems by using optical preamplifiers[J]. Journal of Physics B: Atomic, Molecular and Optical Physics, 42, 114014(2009).

[14] Lodewyck J, Grangier P. Tight bound on the coherent-state quantum key distribution with heterodyne detection[J]. Physical Review A, 76, 022332(2007).

[15] Navascués M, Acín A. Security bounds for continuous variables quantum key distribution[J]. Physical Review Letters, 94, 020505(2005).

[16] Lodewyck J, Bloch M, García-Patrón R et al. Quantum key distribution over 25 km with an all-fiber continuous-variable system[J]. Physical Review A, 76, 042305(2007).

[17] Gao T C, Liu X C, Zhang Y T et al. Relationship research between snowfall and visibility[J]. Journal of PLA University of Science and Technology(Natural Science Edition), 12, 403-408(2011).

[18] Kim I I. McArthur B, Korevaar E J. Comparison of laser beam propagation at 785 nm and 1550 nm in fog and haze for optical wireless communications[J]. Proceedings of SPIE, 4214, 26-37(2001).

[19] Liu X C, Gao T C, Liu L et al. Influences of precipitation on atmospheric extinction coefficient and visibility[J]. Journal of Applied Meteorological Science, 21, 433-441(2010).

[20] Nie M, Chen W, Zhang M L et al. Effects of haze on the free-space quantum state transfer[J]. Journal of Xi'an University of Posts and Telecommunications, 20, 19-23(2015).