Simulation of lidar ratios and Angstr m exponents of different aerosols

Yuehui SONG; Lili SHI; Leilei LU; Shichun LI; Wenhui XIN; Qing YAN; Dengxin HUA

doi:10.3969/j.issn.1007-5461. 2016.01.015

Journals >Chinese Journal of Quantum Electronics >Volume 33 >Issue 1 >Page 98 > Article

Chinese Journal of Quantum Electronics
Vol. 33, Issue 1, 98 (2016)

Simulation of lidar ratios and Angstr m exponents of different aerosols

Yuehui SONG^*, Lili SHI, Leilei LU, Shichun LI, Wenhui XIN, Qing YAN, and Dengxin HUA

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[in Chinese]

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DOI: 10.3969/j.issn.1007-5461. 2016.01.015 Cite this Article

SONG Yuehui, SHI Lili, LU Leilei, LI Shichun, XIN Wenhui, YAN Qing, HUA Dengxin. Simulation of lidar ratios and Angstr m exponents of different aerosols[J]. Chinese Journal of Quantum Electronics, 2016, 33(1): 98 Copy Citation Text

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References

[10] Jung C H, Lee J Y, et al. Changes in the Angstr m exponent during aerosol coagulation and condensation［J］. Asian Journal of Atmospheric Environment, 2012, (4): 304-313.

[11] Choi S C, Baik S H, Park S K, et al. The measurement of the lidar ratio by using the rotational Raman lidar［J］. Journal of the Optical Society of Korea, 2010, 14(3): 174-177.

[15] Hess M, Koepke P, Schult I. Optical properties of aerosols and clouds: The software package OPAC［J］. Bulletin of the American Meteorological Society, 1998, 79(5): 831-844.

[16] Hu Yongxiang. Depolarization ratio-effective lidar ratio relation: Theoretical basis for space lidar cloud phase discrimination［J］. Geophysical Research Letters, 2007, 34(11): 11812-1-11812-4.

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