Abstract
Abstract. From the high spectral resolution thermal infrared observations of the Infrared Atmospheric Sounding Interferometer (IASI) mineral dust AOD (transferred from thermal infrared to 0.5 μm) is retrieved using a Singular Vector Decomposition of brightness temperature spectra. As infrared retrieval based on 8–12 μm observations, dust observation with IASI is independent from solar illumination. Through the linear combinations of suitable independent singular vectors weighted by their contribution to the observed signal, and a projection of different a-priori dust spectra on the resulting signal the dust can be well distinguished from the influence of surface emissivity and gas absorption. In contrast to lookup-table based single-channel retrievals this method takes advantage of the spectral shape of dust extinction and surface and atmosphere influence over the total 8–12 μm window band. Using different a-priori spectra for dust extinction allows also for an estimation of dust particle size in terms of effective radius based on the respective dust model size distributions. These dust models are also used for the transfer of infrared AOD to 0.5 μm. Four months of IASI observations covering Northern Africa and Arabia are used for evaluation. Two large scale dust events, one covering the Arabian Peninsula and adjacent parts of the Indian Ocean, the other over the Atlantic Ocean off the coast of West-Africa, are analysed and compared with other satellite images. They also show the good suitability of IASI data for dust observation at day and night. Monthly means derived from IASI observations represent well the known seasonal cycles of dust activity over Northern Africa and Arabia. IASI Dust AOD0.5 μm and AERONET coarse mode AOD0.5 μm are reasonably well (linearly) correlated with ρ=0.623. Moreover, comparison of time series of AERONET and IASI observations shows that the evolution of dust events is very well covered by the IASI observations. Rank correlation between dust effective radius and AERONET Ångström exponent is −0.557 indicating the general capability of (qualitative) dust particle size information being provided by this method.
Highlights
Airborne mineral dust plays an important role in the climate system as it has several effects which directly or indirectly impact on the atmospheric state and climate
Dust Aerosol Optical Depth (AOD) retrieved from Infrared Atmospheric Sounding Interferometer (IASI) correlates quite well with AERONET coarse mode AOD given the asumptions and constraints of the retrieval and the fact that IASI is only sensitive to the coarse mode dust particles being responsible for considerable extinction in the 8–12 μm band
The retrieval is based on a singular vector decomposition of IASI spectra in the 8–12 μm band rather than on direct simulation of radiative transfer
Summary
Airborne mineral dust plays an important role in the climate system as it has several effects which directly or indirectly impact on the atmospheric state and climate. It reduces surface insolation by extinction of solar radiation (King et al, 1999; Slingo et al, 2006), which is of importance for climate and atmospheric processes, and for solar energy applications (Breitkreuz et al, 2007). Airborne dust activity follows diurnal and seasonal cycles and has a very high spatial variability over Northern Africa and Arabia (Engelstaedter et al, 2006)
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