Abstract
Abstract. The climatic effects of dust aerosols in North Africa have been investigated using the atmospheric general circulation model (AGCM) developed at the University of California, Los Angeles (UCLA). The model includes an efficient and physically based radiation parameterization scheme developed specifically for application to clouds and aerosols. Parameterization of the effective ice particle size in association with the aerosol first indirect effect based on ice cloud and aerosol data retrieved from A-Train satellite observations have been employed in climate model simulations. Offline simulations reveal that the direct solar, IR, and net forcings by dust aerosols at the top of the atmosphere (TOA) generally increase with increasing aerosol optical depth. When the dust semi-direct effect is included with the presence of ice clouds, positive IR radiative forcing is enhanced since ice clouds trap substantial IR radiation, while the positive solar forcing with dust aerosols alone has been changed to negative values due to the strong reflection of solar radiation by clouds, indicating that cloud forcing associated with aerosol semi-direct effect could exceed direct aerosol forcing. With the aerosol first indirect effect, the net cloud forcing is generally reduced in the case for an ice water path (IWP) larger than 20 g m−2. The magnitude of the reduction increases with IWP. AGCM simulations show that the reduced ice crystal mean effective size due to the aerosol first indirect effect results in less OLR and net solar flux at TOA over the cloudy area of the North Africa region because ice clouds with smaller size trap more IR radiation and reflect more solar radiation. The precipitation in the same area, however, increases due to the aerosol indirect effect on ice clouds, corresponding to the enhanced convection as indicated by reduced OLR. Adding the aerosol direct effect into the model simulation reduces the precipitation in the normal rainfall band over North Africa, where precipitation is shifted to the south and the northeast produced by the absorption of sunlight and the subsequent heating of the air column by dust particles. As a result, rainfall is drawn further inland to the northeast. This study represents the first attempt to quantify the climate impact of the aerosol indirect effect using a GCM in connection with A-Train satellite data. The parameterization for the aerosol first indirect effect developed in this study can be readily employed for application to other GCMs.
Highlights
The recent Sahel drought has been recognized as one of the largest climate changes in recent history by the climate research community
The role of direct radiative forcing of dust in the wet-to-dry climate change observed in the Sahel region over the last three decades has been examined by Yoshioka and Mahowald (2007), who showed that precipitation over the inter-tropical convergence zone (ITCZ), including the Sahel region, was reduced, while increased precipitation was found south of the ITCZ, when dust radiative forcing is included in atmospheric general circulation model (AGCM) simulations
The objective of this study is to investigate the impact of dust aerosols on regional climate with a focus on the North Africa region, by examining the responses of the regional climate system to direct, semi-direct, and first indirect aerosol radiative forcings in the UCLA AGCM in terms of the cloud, radiation, temperature, precipitation, and general circulation patterns
Summary
The recent Sahel drought has been recognized as one of the largest climate changes in recent history by the climate research community. Liou et al (2008) recently developed a correlation analysis involving IWC and De on the basis of fundamental thermodynamic principles intended for application to climate models For this purpose, ice crystal size distributions obtained from in situ measurements collected during numerous field campaigns in the tropics, midlatitude, and Arctic regions were used. The objective of this study is to investigate the impact of dust aerosols on regional climate with a focus on the North Africa region, by examining the responses of the regional climate system to direct, semi-direct, and first indirect (with a focus on ice clouds) aerosol radiative forcings in the UCLA AGCM in terms of the cloud, radiation, temperature, precipitation, and general circulation patterns. Radiation calculations can be performed for each of the cloud configurations and the all-sky flux can be determined as the weighted sum of the flux computed for each sector
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