A novel approach based on Fernald’s and Klett’s method to determine the atmospheric extinction coefficient boundary value

Peng-fei TIAN; Lei ZHANG; Xian-jie CAO; Jin WANG; Bi ZHOU; Hong-bin WANG; Zhong-wei HUANG; Wu ZHANG

doi:10.3969/j.issn.1007-5461. 2013.01.011

[1] Charlson R J, Schwartz S E, Hales J M, et al. Climate forcing by anthropogenic aerosols ［J］. Science, 1992, 24: 423-430.

[2] Yasuhiro Sasano. Tropospheric aerosol extinction coefficient profiles derived from scanning lidar measurements over Tsukuba, Japan, from 1990 to 1993 ［J］. Appl. Opt., 1996, 35(24): 4941-4952.

[3] Merlauldl A, Roozendael M V, et al. Airborne DOAS measurements in arctic: Vertical distributions of aerosol extinction coefficient and NO2 concentration ［J］. Atmospheric Chemistry and Physics, 2011, 11(17): 9219-9236.

[4] Pornsarp Pornsawad, Giuseppe D’Amico, Christine Bockmann, et al. Retrieval of aerosol extinction coefficient profiles from Raman lidar data by inversion method ［J］. Appl. Opt., 2012, 51(12): 2035-2044.

[5] Collis R T H. Lidar: a new atmospheric probe ［J］. Quarterly Journal of the Royal Meteorological Society, 1967, 93(398): 553-555.

[6] Collis R T H, Russell P B. Lidar Measurement of Particles and Gases by Elastic Backscattering and Differential Absorption in Laser Monitoring of the Atmosphere ［M］. Heidelberg: Springer Berlin, 1976: 71-102.

[7] Klett J D. Stable analytical inversion solution for processing lidar returns ［J］. Appl. Opt., 1981, 20(2): 211-220.

[8] Klett J D. Lidar inversion with variable backscatter/extinction ratios ［J］. Appl. Opt., 1985, 24(11): 1638-1643.

[9] Fernald F G. Analysis of atmospheric lidar observations: Some comments ［J］. Appl. Opt., 1984, 23(2): 652-653.

[16] Christian C M, Todd K M, Jacob H G. An iterative least square approach to elastic-lidar retrievals for well-characterized aerosols ［J］. IEEE Transactions on Geoscience and Remote Sensing, 2010, 48(5): 2430-2444.

[19] Huang J P, Zhang W, Zuo J Q, et al. An overview of the semi-arid climate and environment research observatory over the loess plateau ［J］. Advances in Atmospheric Sciences, 2008, 25(6): 906-921.

[22] Zhang L, Cao X, Bao J, et al. A case study of dust aerosol radiative properties over Lanzhou, China ［J］. Atmospheric Chemistry and Physics, 2010, 10(9): 4283-4293.

[23] Ge J M, Su J, Ackerman T P, et al. Dust aerosol optical properties retrieval and radiative forcing over northwestern China during the 2008 China-U.S. joint field experiment ［J］. Journal of Geophysical Research, 2010, 115: D00K12.

[25] Holben B N, Eck T F, Slutsker J, et al. AERONET-A federated instrument network and data archive for aerosol characterization ［J］. Remote Sens. Environ., 1998, 6(1): 1-16.

[26] Eck T F, Holben B N, Reid J S, et al. Wavelength dependence of the optical depth of biomass burning, urban and desert dust aerosols ［J］. Journal of Geophysical Research, 1999, 104(31): 331-350.

[28] Kovalev V A. Sensitivity of the lidar solution to errors of the aerosol backscatter-to-extinction ratio: Influence of a monotonic change in the aerosol extinction coefficient ［J］. Appl. Opt., 1995, 34(18): 3457-3462.

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