Abstract
Abstract. This study presents an original method to evaluate key parameters for the estimation of the direct radiative effect (DRE) of aerosol above clouds: the absorption of the the cloud albedo. It is based on multi-angle total and polarized radiances both provided by the A-train satellite instrument POLDER – Polarization and Directionality of Earth Reflectances. The sensitivities brought by each kind of measurements are used in a complementary way. Polarization mostly translates scattering processes and is thus used to estimate scattering aerosol optical thickness and aerosol size. On the other hand, total radiances, together with the scattering properties of aerosols, are used to evaluate the absorption optical thickness of aerosols and cloud optical thickness. The retrieval of aerosol and clouds properties (i.e., aerosol and cloud optical thickness, aerosol single scattering albedo and Ångström exponent) is restricted to homogeneous and optically thick clouds (cloud optical thickness larger than 3). In addition, a procedure has been developed to process the shortwave DRE of aerosols above clouds. Three case studies have been selected: a case of absorbing biomass burning aerosols above clouds over the southeast Atlantic Ocean, a Siberian biomass burning event and a layer of Saharan dust above clouds off the northwest coast of Africa. Besides these case studies, both algorithms have been applied to the southeast Atlantic Ocean and the results have been averaged during August 2006. The mean DRE is found to be 33.5 W m−2 (warming). Finally, the effect of the heterogeneity of clouds has been investigated and reveals that it affects mostly the retrieval of the cloud optical thickness and not greatly the aerosols properties. The homogenous cloud assumption used in both the properties retrieval and the DRE processing leads to a slight underestimation of the DRE.
Highlights
The quantification of the aerosol radiative impact is one of the largest sources of uncertainty in global climate models (Myhre et al, 2013b)
We introduced a new approach for the retrieval of aerosol and cloud properties (i.e., AOT, Single scattering albedo (SSA) and cloud optical thickness (COT)) when an aerosol layer lies above a liquid cloud over the ocean
Its range of application is restricted to homogeneous clouds with COT values larger than 3
Summary
The quantification of the aerosol radiative impact is one of the largest sources of uncertainty in global climate models (Myhre et al, 2013b). The latter is modeled thanks to cloud properties derived from SCIAMACHY measurements in the shortwave infrared spectrum While this method is expected to work efficiently for finemode aerosols as their interactions at longer wavelengths are minimal or even non-existent, it may not work for coarsemode dust aerosols due to their radiative influence at longer wavelengths. Aerosol absorption properties are expected to vary a lot depending on space, time and formation processes (Dubovik et al, 2002) and resulting in different radiative responses Both algorithms have been applied to three events with contrasted aerosol properties: absorbing biomass burning aerosols off the southwest coast of Africa, and scattering ones from Siberia and Saharan dust.
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