Geophysical Fluid Dynamics Laboratory, National Oceanic and Atmospheric Administration

The realistic simulation of the summer Mediterraneanclimaterequires not only refined spatial scales, but also an adequate representation of land-atmosphere interactions andteleconnections. Addressing all of these issues remains a challenge for most of the CMIP3/CMIP5 generation models. In this study we analyze high-24resolution (~0.5° lat x lon) RCP8.5 future projections of the Geophysical Fluid Dynamics Laboratory CM2.5 model with anew incorporatedland model (LM3). The simulated regional future changes suggest pronounced warming and drying over mostparts of the Mediterranean. However the changes aredistinctivelyless radical when compared with the CMIP5 multimodel ensemble. Moreover, changes over the Southeast (off the coast area of the Balkans) and Central Europe indicate not only a very modest warming, compared to the CMIP5 projections, but also wetting tendencies. The difference of CM2.5 projections of future changes over previous-generation modelshighlights the mportance of a) a correctlyprojectedmagnitude of changes of the North Atlantic Oscillation and its regional impacts, which have thecapacity to partly offset the anthropogenicwarming and drying over the western andcentral Mediterranean; b) a refined representation of land surface-atmospheric interactions, whichare a governing factor for thermal-and hydro-climate over Central and SoutheasternEurope. The CM2.5 projections also indicate a maximum of warming (Levant) and drying (Asia Minor) over the eastern Mediterranean. The changes derived in this region indicate a decreasing influence of atmospheric dynamics in maintaining the regional temperature and precipitation balance and instead an increasing influence of local surface temperature on the local surface atmospheric circulation.