Abstract
Abstract. Since the 1980s several spaceborne sensors have been used to retrieve the aerosol optical depth (AOD) over the Mediterranean region. In parallel, AOD climatologies coming from different numerical model simulations are now also available, permitting to distinguish the contribution of several aerosol types to the total AOD. In this work, we perform a comparative analysis of this unique multi-year database in terms of total AOD and of its apportionment by the five main aerosol types (soil dust, sea-salt, sulfate, black and organic carbon). We use 9 different satellite-derived monthly AOD products: NOAA/AVHRR, SeaWiFS (2 products), TERRA/MISR, TERRA/MODIS, AQUA/MODIS, ENVISAT/MERIS, PARASOL/POLDER and MSG/SEVIRI, as well as 3 more historical datasets: NIMBUS7/CZCS, TOMS (onboard NIMBUS7 and Earth-Probe) and METEOSAT/MVIRI. Monthly model datasets include the aerosol climatology from Tegen et al. (1997), the climate-chemistry models LMDz-OR-INCA and RegCM-4, the multi-model mean coming from the ACCMIP exercise, and the reanalyses GEMS and MACC. Ground-based Level-2 AERONET AOD observations from 47 stations around the basin are used here to evaluate the model and satellite data. The sensor MODIS (on AQUA and TERRA) has the best average AOD scores over this region, showing a relevant spatio-temporal variability and highlighting high dust loads over Northern Africa and the sea (spring and summer), and sulfate aerosols over continental Europe (summer). The comparison also shows limitations of certain datasets (especially MERIS and SeaWiFS standard products). Models reproduce the main patterns of the AOD variability over the basin. The MACC reanalysis is the closest to AERONET data, but appears to underestimate dust over Northern Africa, where RegCM-4 is found closer to MODIS thanks to its interactive scheme for dust emissions. The vertical dimension is also investigated using the CALIOP instrument. This study confirms differences of vertical distribution between dust aerosols showing a large vertical spread, and other continental and marine aerosols which are confined in the boundary layer. From this compilation, we propose a 4-D blended product from model and satellite data, consisting in monthly time series of 3-D aerosol distribution at a 50 km horizontal resolution over the Euro-Mediterranean marine and continental region for the 2003–2009 period. The product is based on the total AOD from AQUA/MODIS, apportioned into sulfates, black and organic carbon from the MACC reanalysis, and into dust and sea-salt aerosols from RegCM-4 simulations, which are distributed vertically based on CALIOP climatology. We extend the 2003–2009 reconstruction to the past up to 1979 using the 2003–2009 average and applying the decreasing trend in sulfate aerosols from LMDz-OR-INCA, whose AOD trends over Europe and the Mediterranean are median among the ACCMIP models. Finally optical properties of the different aerosol types in this region are proposed from Mie calculations so that this reconstruction can be included in regional climate models for aerosol radiative forcing and aerosol-climate studies.
Highlights
The Mediterranean region has been identified as a crossroads of air masses carrying numerous and various aerosol types (Lelieveld et al, 2002), and the relatively high aerosol load encountered over the region can potentially lead to strong effects on the regional radiative budget, climate and ecosystems of the Mediterranean (Rodaet al., 1993; Rosenfeld et al, 2001; Bergamo et al, 2008; Guieu et al, 2010)
Several Aerosol Optical Depth (AOD) datasets exist over the Mediterranean region, both satellite-derived (e.g., MODerate resolution Imaging Spectroradiometer (MODIS), Multiangle Imaging SpectroRadiometer (MISR), SEVIRI) and model-simulated products (e.g., Monitoring Atmospheric Composition and Climate (MACC), RegCM-4) which will be discussed in Sect
This study has shown that the MODIS AOD product has the most reliable estimate of the total AOD over ocean and land
Summary
The Mediterranean region has been identified as a crossroads of air masses carrying numerous and various aerosol types (Lelieveld et al, 2002), and the relatively high aerosol load encountered over the region can potentially lead to strong effects on the regional radiative budget, climate and ecosystems of the Mediterranean (Rodaet al., 1993; Rosenfeld et al, 2001; Bergamo et al, 2008; Guieu et al, 2010). Numerous anthropogenic and natural sources over this region lead to the presence of different aerosols, such as industrial and urban aerosols from Europe and North African towns, forest fires, biomass burning from Eastern Europe, dust aerosols from Africa and marine particles This diversity results in a large variety in physico-chemical and optical aerosol properties over the basin (Basart et al, 2009), highly variable in space and time, driving their interactions with shortwave (SW) and longwave (LW) radiation, with ensuing impacts on climate. The atmospheric aerosol content can be represented by the Aerosol Optical Depth (AOD), which is the vertical integral over an atmospheric column of the fraction of incident light scattered and absorbed by aerosols This optical parameter is often used as input for calculations of aerosol direct and semi-direct radiative forcing in Regional Climate Models (RCMs). Over the Mediterranean region, an intercomparison between all these sensors and models has not been done to our knowledge
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