Abstract
Abstract. As part of the international project entitled "African Monsoon Multidisciplinary Analysis (AMMA)", NAMMA (NASA AMMA) aimed to gain a better understanding of the relationship between the African Easterly Waves (AEWs), the Sahara Air Layer (SAL), and tropical cyclogenesis. The NAMMA airborne field campaign was based out of the Cape Verde Islands during the peak of the hurricane season, i.e., August and September 2006. Multiple Sahara dust layers were sampled during 62 encounters in the eastern portion of the hurricane main development region, covering both the eastern North Atlantic Ocean and the western Saharan desert (i.e., 5–22° N and 10–35° W). The centers of these layers were located at altitudes between 1.5 and 3.3 km and the layer thickness ranged from 0.5 to 3 km. Detailed dust microphysical and optical properties were characterized using a suite of in-situ instruments aboard the NASA DC-8 that included a particle counter, an Ultra-High Sensitivity Aerosol Spectrometer, an Aerodynamic Particle Sizer, a nephelometer, and a Particle Soot Absorption Photometer. The NAAMA sampling inlet has a size cut (i.e., 50% transmission efficiency size) of approximately 4 μm in diameter for dust particles, which limits the representativeness of the NAMMA observational findings. The NAMMA dust observations showed relatively low particle number densities, ranging from 268 to 461 cm−3, but highly elevated volume density with an average at 45 μm3 cm−3. NAMMA dust particle size distributions can be well represented by tri-modal lognormal regressions. The estimated volume median diameter (VMD) is averaged at 2.1 μm with a small range of variation regardless of the vertical and geographical sampling locations. The Ångström Exponent assessments exhibited strong wavelength dependence for absorption but a weak one for scattering. The single scattering albedo was estimated at 0.97 ± 0.02. The imaginary part of the refractive index for Sahara dust was estimated at 0.0022, with a range from 0.0015 to 0.0044. Closure analysis showed that observed scattering coefficients are highly correlated with those calculated from spherical Mie-Theory and observed dust particle size distributions. These values are generally consistent with literature values reported from studies with similar particle sampling size range.
Highlights
A recent analysis of MODIS (Moderate-Resolution Imaging Spectroradiometer) satellite observations indicates that an average of 240 ± 80 Tg of mineral dust is transported from the Saharan Desert each year downwind over the North Atlantic by the prevailing trade winds (Kaufman et al, 2005)
Multiple free tropospheric Saharan dust layers were sampled during the 62 encounters in the eastern North Atlantic during the NAMMA airborne campaign, which took place in August and September, 2006
The NAMMA study area extended over the region between 10– 25◦ N and 10–35◦ W, which overlaps the eastern part of the Hurricane Main Development Region
Summary
A recent analysis of MODIS (Moderate-Resolution Imaging Spectroradiometer) satellite observations indicates that an average of 240 ± 80 Tg of mineral dust is transported from the Saharan Desert each year downwind over the North Atlantic by the prevailing trade winds (Kaufman et al, 2005). In a more recent work, Zhang et al (2009) showed that dust could indirectly affect the eyewall development by modifying the latent heat release in rainbands Both studies note that more detailed observational information on Saharan dust microphysical properties and vertical distributions is needed to further develop a mechanistic understanding of the potential effects of dust on hurricane genesis and intensity. A number of recent airborne and ground based field campaigns were conducted under the framework of African Monsoon Multidisciplinary Analysis (AMMA) international project (http://amma.mediasfrance.org/) to investigate, among other things, Saharan dust generation, transport and regional impacts These studies were focused over the eastern Tropical Atlantic and North Africa and carried out various measurements of Saharan dust spatial distributions and characteristics, including optical, chemical, and microphysical properties.
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