Abstract
Abstract. Experimental estimations of the infrared refractive index of African mineral dust have been retrieved from laboratory measurements of particle transmission spectra in the wavelength range 2.5–25 μm. Five dust samples collected at Banizoumbou (Niger) and Tamanrasset (Algeria) during dust events originated from different Western Saharan and Sahelian areas have been investigated. The real (n) and imaginary (k) parts of the refractive index obtained for the different dust samples vary in the range 1.1–2.7 and 0.05–1.0, respectively, and are strongly sensitive to the mineralogical composition of the particles, especially in the 8–12 and 17–25 μm spectral intervals. Dust absorption is controlled mainly by clays (kaolinite, illite, smectite) and, to a lesser extent, by quartz and calcium-rich minerals (e.g. calcite, gypsum). Significant differences are obtained when comparing our results with existing experimental estimations available in the literature, and with the values of the OPAC (Optical Properties of Aerosols and Clouds) database. The different data sets appear comparable in magnitude, with our values of n and k falling within the range of variability of past studies. However, literature data fail in accurately reproducing the spectral signatures of the main minerals, in particular clays, and they significantly overestimate the contribution of quartz. Furthermore, the real and the imaginary parts of the refractive index from some literature studies are found not to verify the Kramers–Kronig relations, thus being theoretically incorrect. The comparison between our results, from western Africa, and literature data, from different locations in Europe, Africa, and the Caribbean, nonetheless, confirms the expected large variability of the dust infrared refractive index. This highlights the necessity for an extended systematic investigation of dust properties at infrared wavelengths. For the five analysed dust samples, aerosol intensive optical properties relevant to radiative transfer (mass extinction efficiency, kext, single scattering albedo, ω, and asymmetry factor, g) have been calculated, by using the Mie theory, based on the estimated refractive index and measured particle size distribution. The optical properties show a large sample-to-sample variability, with kext, ω, and g varying in the range 0.05–0.35, 0.25–1.0, and 0.05–0.75. This variability is expected to significantly impact satellite retrievals of atmospheric and surface parameters (e.g. from the Infrared Atmospheric Sounding Interferometer, IASI) and estimates of the dust radiative forcing.
Highlights
Mineral dust is one of the most abundant aerosol species in the atmosphere and strongly contributes to the total aerosol content (Textor et al, 2007; Huneeus et al, 2012)
In this paper we have presented new experimental estimates of the infrared complex refractive index of African mineral dust
Spectroscopy measurements have been performed on five natural dust samples collected at the sites of Banizoumbou (Niger) and Tamanrasset (Algeria) during the AMMA campaign in 2006 and which originated in different Western Saharan and Sahelian source regions
Summary
Mineral dust is one of the most abundant aerosol species in the atmosphere and strongly contributes to the total aerosol content (Textor et al, 2007; Huneeus et al, 2012). The arid and semiarid regions of West Africa, i.e. the Sahara and the Sahel, account for more than 60 % of the total annual dust emission, and are by far the most significant sources of mineral dust at the global scale (Prospero et al, 2002; Laurent et al, 2008; Ginoux et al, 2012). Mineral dust directly affects the planetary radiative balance by absorption and scattering of radiation (Sokolik and Toon, 1996). Due to their high atmospheric load, dust aerosols are observed to exert a significant radiative effect both close to source regions and in transport areas (Haywood et al, 2003; Highwood et al, 2003; Di Biagio et al, 2010). The implications on the hydrological cycle, in particular, are of great relevance for water-stressed semiarid areas, as it is the case of the Sahel, mainly in relation to possible feedback mechanisms on dust emission in these regions (Carlsaw et al, 2010)
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