Abstract. Accurate lidar ratio (LR) and better understanding of its
variation characteristics can not only improve the retrieval accuracy of
parameters from elastic lidar, but also play an important role in assessing
the impacts of aerosols on climate. Using the observational data of a Raman
lidar in Shanghai from 2017 to 2019, LRs at 355 nm were retrieved and their
variations and influence factors were analyzed. Within the height range of
0.5–5 km, about 90 % of the LRs were distributed in 10–80 sr with
an average value of 41.0 ± 22.5 sr, and the LR decreased with the
increase in height. The volume depolarization ratio (δ) was
positively correlated with LR, and it also decreased with the increase in
height, indicating that the vertical distribution of particle shape was one of
the influence factors of the variations in LR with height. LR had a strong
dependence on the original source of air masses. Affected by the aerosols
transported from the northwest, the average LR was the largest,
44.2 ± 24.7 sr, accompanied by the most irregular particle shape. The vertical
distribution of LR was affected by atmospheric turbidity, with the greater
gradient of LR under clean conditions. The LR above 1 km could be more than
80 sr, when Shanghai was affected by biomass burning aerosols.
Toward the Kashi region in northwest of China, the Moderate Resolution Imaging Spectroradiometer (MODIS) aerosol optical depth (AOD) retrievals from Collection 6 (C6) MYD, Collection 6.1 (C6.1) MOD, and C6.1 MYD during 2016–2017 are compared with ground‐based measurements from the Sun‐sky Radiometer Network (SONET), and the first comprehensive evaluation of the Dark Target (DT) and Deep Blue (DB) retrievals with a 10‐km spatial resolution in the latest C6.1 MYD AOD data set during 2016–2018 is presented. In general, C6.1 MYD AOD products (both of DT and DB algorithm) are the most effective in Kashi of the three collections, and there is an overall underestimation of DB AOD, while DT AOD that slightly outperformed DB AOD in Kashi is overestimated on the whole. As to the factors that influence the accuracy of MODIS AOD, for DB algorithm, the overestimations of the surface reflectance and Single Scattering Albedo that DB aerosol model assumed can cause underestimation of DB AOD retrievals over Kashi, while the ones for DT algorithm are opposite. Besides, the coarse dust particles with lower veracity are predominant in Kashi region, which illustrated that the errors of particle size assumption in C6.1 MYD DT and DB algorithms will make large inversion error of MODIS AOD. Moreover, whatever DB or DT algorithm, the accuracy of AOD is diminished as the aerosol loading increases. The more realistic aerosol models and surface characterizations are necessary during the process of generating the MODIS aerosol retrievals in Kashi region.
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