Abstract
Abstract. Physical and optical properties of atmospheric aerosols collected by using a high resolution (1.5 nm) spectroradiometer (spectral range 400–800 nm), a 13-stage Dekati Low Pressure Impactor (size range 30 nm–10 μm), and an AE31 Aethalometer (7 wavelenghts from 370 nm to 950 nm), have been examined in a semi-rural site in Southwest Italy (Tito Scalo, 40°35' N, 15°41' E, 750 m a.s.l.). In particular, daily averaged values of AOD and Ångström turbidity parameters from radiometric data together with mass-size distributions from impactor data and Black Carbon (BC) concentrations have been analyzed from May to October 2008. Furthermore, by inverting direct solar radiances, aerosol columnar number and volume size distributions have been obtained for the same period. The comparison of different observation methods, allowed to verify if, and in what conditions, changes in aerosol properties measured at ground are representative of columnar properties variations. Agreement between columnar and in-situ measurements has been obtained in case of anthropogenic aerosol loading, while in case of Saharan dust intrusions some discrepancies have been found when dust particles were located at high layers in the atmosphere (4–8 km) thus affecting columnar properties more than surface ones. For anthropogenic aerosols, a good correlation has been confirmed through the comparison of fine aerosol fraction contribution as measured by radiometer, impactor and aethalometer, suggesting that, in this case, the particles are more homogeneously distributed over the lower layers of atmosphere and columnar aerosol optical properties are dominated by surface measured component.
Highlights
At present time aerosols are recognized to be responsible for a significant impact on climate change affecting our environment
Typical mass size distributions obtained from DLPI data for the analyzed measurement period show a prevailing bimodal pattern with the accumulation mode oscillating in the range 0.27 μm–0.39 μm and a coarse mode centred at 2.4 μm
In the case of traffic aerosol, measured near the footpath of a very busy street without other major aerosol sources, mass size distributions showed a peak in the dimensional range 0.32– 0.56 μm
Summary
At present time aerosols are recognized to be responsible for a significant impact on climate change affecting our environment. According to IPCC 2007, improved and intensified in situ observations together with remote sensing of aerosols could better constrain the range of aerosol radiative forcing. The analysis of AOD spectral dependence expressed by the Angstrom exponent α and the study of a relationship between AOD and α can be useful to distinguish different aerosol types. On this subject Masmoudi et al, 2003 identified aerosol source region in different sites of the Mediterranean basin analysing Angstrom exponent α variation as a function of the aerosol optical thickness at 870 nm. As a further support to aerosol characterization, inversions can be performed from radiometric measurements to obtain both columnar volume and number size distributions
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