Plant Soil Environ., 2009, 55(6):257-266 | DOI: 10.17221/1017-PSE

Climate-driven changes of production regions in Central Europe

M. Trnka1, J. Eitzinger2, P. Hlavinka1, M. Dubrovský1, 3, D. Semerádová1, 3, P. Štěpánek4, S. Thaler2, Z. Žalud1, 3, M. Možný4, H. Formayer2
1 Institute of Agrosystems and Bioclimatology, Mendel University of Agriculture and Forestry Brno, Czech Republic
2 Institute of Meteorology, University of Natural Resources and Applied Life Sciences, Vienna, Austria
3 Institute of Atmospheric Physics, Czech Academy of Sciences, Prague, Czech Republic
4 Czech Hydrometeorological Institute, Department of Meteorology and Climatology, Brno, Czech Republic

The presented work complements studies on agroclimatic zoning that were performed during 19th and 20th century in the Czech Republic and Austria and allows estimating the effect of climate change on the spatial distribution of agroclimatic conditions within both countries. The main conclusions of the study are: (1) The combination of increased air temperature and changes in the amount and distribution of precipitation will lead to significant shifts in the agroclimatic zones by the 2020's. The current most productive areas will be reduced and replaced by warmer but drier conditions, which are considered less suitable for rainfed farming. (2) While trends in the changes expected in lowlands are mostly negative (especially for non-irrigated crops), higher elevations might experience improvement in their agroclimatic production potential. However, the production potential of these regions is usually limited by other factors such as the soil quality and terrain accessibility. Additionally, these positive effects might be shortlived, as by the 2050's, even the areas in higher altitudes might experience much drier conditions than nowadays. (3) Dairy-oriented agriculture (based on permanent grassland production) at higher altitudes could suffer through an increased evapotranspiration demand combined with a decrease in precipitation, leading to higher water deficits and yield variations. (4) All above listed changes will most likely occur within less than four decades. The rate of change might be so high that the concept of agroclimatic zoning itself might lose its relevance due to the perpetual change.

Keywords: climate change; agroclimatic zoning; water deficit; growing season; AgriClim

Published: June 30, 2009  Show citation

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Trnka M, Eitzinger J, Hlavinka P, Dubrovský M, Semerádová D, Štěpánek P, et al.. Climate-driven changes of production regions in Central Europe. Plant Soil Environ.. 2009;55(6):257-266. doi: 10.17221/1017-PSE.
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