1Institute for Meteorology and Climate Research, Karlsruhe Institute of Technology, Karlsruhe, Germany
2School of Earth and Atmospheric Sciences, Georgia Institute of Technology, Atlanta, GA, USA
3School of Chemical and Biomolecular Engineering, Georgia Institute of Technology, Atlanta, GA, USA
4Global Modeling and Assimilation Office, NASA GSFC, Greenbelt, MD, USA
5I.M. Systems Group, Rockville, MD, USA
6SABIC-Innovative Plastics, Selkirk, NY, USA
7Deutscher Wetterdienst, Offenbach, Germany
Abstract. We investigated the impact of mineral dust particles on clouds, radiation and atmospheric state during a strong Saharan dust event over Europe in May 2008, applying a comprehensive online-coupled regional model framework that explicitly treats particle microphysics and chemical composition. Sophisticated parameterizations for aerosol activation and ice nucleation, together with two-moment cloud microphysics are used to calculate the interaction of the different particles with clouds depending on their physical and chemical properties.
The impact of dust on cloud droplet number concentration was found to be low, with just a slight increase in cloud droplet number concentration for both uncoated and coated dust. For temperatures lower than the level of homogeneous freezing, no significant impact of dust on the number and mass concentration of ice crystals was found, though the concentration of frozen dust particles reached up to 100 l−1 during the ice nucleation events. Mineral dust particles were found to have the largest impact on clouds in a temperature range between freezing level and the level of homogeneous freezing, where they determined the number concentration of ice crystals due to efficient heterogeneous freezing of the dust particles and modified the glaciation of mixed phase clouds.
Our simulations show that during the dust events, ice crystals concentrations were increased twofold in this temperature range (compared to if dust interactions are neglected). This had a significant impact on the cloud optical properties which caused a reduction in the incoming short-wave radiation at the surface up to −75 W m−2 in areas with high dust concentrations. Including the direct interaction of dust with radiation caused an additional reduction in the incoming short-wave radiation which was found to be in the order of −40 to −80 W m−2. In contrast to the aerosol-cloud interaction only simulation, the incoming long-wave radiation at the surface was increased significantly in the order of +10 W m−2.
The strong radiative forcings associated with dust caused a~reduction in surface temperature in the order of −0.2 to −0.5 K for most parts of France, Germany, and Italy during the dust event. The maximum difference in surface temperature was found in the East of France, the Benelux, and Western Germany with up to −1 K.
This magnitude of temperature change was sufficient to explain a systematic bias in numerical weather forecasts during the period of the dust event.