[1] Wang T Y[M]. Quantum communication technology and its application prospect, 2013, 197-198.

[2] Yan Y Q. Review of quantum communication[J]. Guangdong Communication Technology, 37, 2-4, 9(2017).

[3] Xie Z[J]. Current situation and prospect of quantum communication Digital Communication World, 2018, 161.

[4] Zhou Z Q, Han Y J, Li C F et al. Solid state quantum memory[J]. China Basic Science, 22, 30-35(2020).

[6] Nie M, Chang L, Yang G et al. Influence of different mixing patterns of haze particles and water cloud particles on the performance of quantum satellite communication[J]. Acta Photonica Sinica, 46, 0701002(2017).

[7] Pan Y. Research on the effects of variable ocean climate factors on the performance of quantum communication[D]. Xi’an: Xi’an University of Posts and Telecommunications, 31-49(2019).

[8] Zhang X Z, Xu X, Liu B Y et al. Influence of marine aerosols on performance of free-space quantum communication[J]. Acta Optica Sinica, 40, 2027001(2020).

[9] Wang H L, Zhu B, An J L et al. Size distribution and characterization of OC and EC in atmospheric aerosols during the Asian youth games of Nanjing, China[J]. Environmental Science, 35, 3271-3279(2014).

[10] Li J. Numerical simulation of optical properties of black carbon aerosol[D]. Nanjing: Nanjing University of Information Science and Technology, 5-16(2014).

[11] Zheng Y N. Morphological analysis and calculation on the light scattering properties of soot aggregates in atmospheric aerosol[D]. Harbin: Harbin University of Science and Technology, 2-7(2017).

[12] Huang G, Liu W, Liu Z H et al. A research overview of black carbon aerosols[J]. Journal of Catastrophology, 30, 205-214(2015).

[13] Zheng L J, Cheng T H, Wu Y et al. Effect of aggregated black carbon aging on infrared absorption and longwave radiative forcing[J]. Acta Physica Sinica, 66, 160201(2017).

[14] Ma X X. Study on climate effects of black carbon aerosol and their sensitivity to size distribution and optical parameters over China[D]. Nanjing: Nanjing University(2017).

[15] Dai B, Luo X D, Chang H M et al. Study on calculating method of aerosol extinction coefficients[J]. Environmental Science & Technology, 31, 12-15(2008).

[16] Nie M, Kou W X, Wei R Y et al. Cell soft handover strategy for 6G network of quantum mobile communication based on optimal entanglement degree[J]. Laser & Optoelectronics Progress, 57, 152701(2020).

[17] Yin H, Han Y[M]. Quantum communications theory and technology, 76-83(2013).

[18] Levoni C, Cervino M, Guzzi R et al. Atmospheric aerosol optical properties: a database of radiative characteristics for different components and classes[J]. Applied Optics, 36, 8031-8041(1997).

[19] Chen H W[M]. A brief course of quantum information and quantum computing, 180-185(2006).

[20] 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).

[21] Liu J, Zhao S M. Capacity of the quantum multiple access depolarizing channel[J]. Chinese Journal of Quantum Electronics, 25, 437-442(2008).

[22] Zhang L, Nie M, Liu X H et al. Study on survival function of noise quantum channel and its simulation[J]. Acta Physica Sinica, 62, 150301(2013).

[23] Yan Y. Research on some issues of quantum communication in free space[D]. Xi’an: Xidian University, 39-55(2009).

[24] Zhang G Y, Yu S Y, Ma J et al. Influence of background light on quantum bit error rate in satellite-to-ground quantum key distribution[J]. Opto-Electronic Engineering, 34, 126-129(2007).

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