Varying soil moisture–atmosphere feedbacks explain divergent temperature extremes and precipitation projections in central Europe

• Published in: Earth system dynamics Vol. 9; no. 3; pp. 1107 - 1125
• Main Authors: Vogel, Martha M, Zscheischler, Jakob, Seneviratne, Sonia I
• Format: Journal Article
• Language: English
• Published: Gottingen Copernicus GmbH 30.08.2018; Copernicus Publications
• Subjects: Agricultural economics; Analysis; Anthropogenic climate changes; Anthropogenic factors; Atmosphere; Atmospheric models; Biogeochemical cycles; Climate change; Climate models; Climatic extremes; Coupling; Economic impact; Environmental aspects; Environmental impact; Extreme weather; Forecasts and trends; Global climate; Global climate models; Global temperatures; Global warming; Heat flux; Heat stress; Heat tolerance; Heat transfer; Human influences; Intercomparison; Latent heat; Latent heat flux; Mean temperatures; Net radiation; Precipitation; Radiation; Radiation balance; Rainfall; Regional climates; Regional development; Soil; Soil moisture; Soil temperature; Summer; Summer precipitation; Temperature; Temperature changes; Temperature effects; Temperature extremes; Uncertainty; Water supply; Europe; Central Europe
• ISSN: 2190-4987; 2190-4979; 2190-4987
• DOI: 10.5194/esd-9-1107-2018

The frequency and intensity of climate extremes is expected to increase in many regions due to anthropogenic climate change. In central Europe extreme temperatures are projected to change more strongly than global mean temperatures, and soil moisture–temperature feedbacks significantly contribute to this regional amplification. Because of their strong societal, ecological and economic impacts, robust projections of temperature extremes are needed. Unfortunately, in current model projections, temperature extremes in central Europe are prone to large uncertainties. In order to understand and potentially reduce the uncertainties of extreme temperature projections in Europe, we analyze global climate models from the CMIP5 (Coupled Model Intercomparison Project Phase 5) ensemble for the business-as-usual high-emission scenario (RCP8.5). We find a divergent behavior in long-term projections of summer precipitation until the end of the 21st century, resulting in a trimodal distribution of precipitation (wet, dry and very dry). All model groups show distinct characteristics for the summer latent heat flux, top soil moisture and temperatures on the hottest day of the year (TXx), whereas for net radiation and large-scale circulation no clear trimodal behavior is detectable. This suggests that different land–atmosphere coupling strengths may be able to explain the uncertainties in temperature extremes. Constraining the full model ensemble with observed present-day correlations between summer precipitation and TXx excludes most of the very dry and dry models. In particular, the very dry models tend to overestimate the negative coupling between precipitation and TXx, resulting in a warming that is too strong. This is particularly relevant for global warming levels above 2 ∘C. For the first time, this analysis allows for the substantial reduction of uncertainties in the projected changes of TXx in global climate models. Our results suggest that long-term temperature changes in TXx in central Europe are about 20 % lower than those projected by the multi-model median of the full ensemble. In addition, mean summer precipitation is found to be more likely to stay close to present-day levels. These results are highly relevant for improving estimates of regional climate-change impacts including heat stress, water supply and crop failure for central Europe.