High-resolution climate change simulations for the Jordan River area

For the estimation of future climate conditions in the Jordan River region, the National Center for Atmospheric Research–Penn State University meteorology model in the versions 3.5 and 3.7 driven with boundary data from the Max‐Planck‐Institute for Meteorology and Hadley Centre global circulation mo...

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Bibliographic Details
Published in:	Journal of Geophysical Research Vol. 116; no. D16
Main Authors:	Smiatek, G., Kunstmann, H., Heckl, A.
Format:	Journal Article
Language:	English
Published:	Washington, DC Blackwell Publishing Ltd 27-08-2011 American Geophysical Union
Subjects:	Atmosphere Atmospheric research Climate change Climatic conditions Coefficient of variation Earth Earth sciences Earth, ocean, space Emissions Exact sciences and technology GCM Geophysics Heat waves Jordan River Meteorology precipitation RCM Regions Rivers Seasonal variations temperature Water availability Middle East Asia Jordan River Israel, Jordan R Atmospheric condition Dog days General circulation models atmospheric precipitation meteorology Scale reduction Bias digital simulation climate variability frequency duration intensity dynamics water resources temperature spatial resolution transient phenomena seasonal variations Comparative study climate change high resolution statistics
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Summary:	For the estimation of future climate conditions in the Jordan River region, the National Center for Atmospheric Research–Penn State University meteorology model in the versions 3.5 and 3.7 driven with boundary data from the Max‐Planck‐Institute for Meteorology and Hadley Centre global circulation models and the Special Report on Emission Scenarios A1B emission scenario has been used. The spatial resolution of the nested dynamic downscaling approach was 18.6 km, and the transient runs were performed for the period 1960–2099. The investigated statistics include mean precipitation, frequency and intensity of wet days and strong precipitation events, as well as mean temperature and heat wave duration index. The results show that the models satisfactorily reproduce the mean temperature and precipitation patterns. The comparison with the observational reference for the period 1961–1990 reveals a bias in the annual mean precipitation ranging from −20% to +17%, with an ensemble mean of −3%. The models show limitations in reproducing the precipitation seasonality. All models underestimate the wet day frequency and show differences in the strong precipitation events. The simulations of the future climate signal indicate an ensemble mean increase of the annual mean temperature of approximately 2.1 K in the period 2031–2060 and 3.7 K for the period 2070–2099 related to the 1961–1991 mean. In the same periods, the annual mean precipitation is simulated to decrease by approximately −11.5% and −20%, respectively, which means a reduction of expected water availability in the Jordan River region. All models show an increase of the heat wave duration index. A significant elevation dependence is present in the simulated future climate signal on both temperature and precipitation. The simulations show an increased coefficient of variation in annual precipitation, indicating that larger interannual precipitation variability can be expected in the future. Key Points Significant reduction of expected water availability in the Jordan River region Significant elevation signal present in the simulated future climate Increased coefficient of variation in simulated future annual precipitation
Bibliography:	Tab-delimited Table 1.Tab-delimited Table 2.Tab-delimited Table 3.Tab-delimited Table 4.Tab-delimited Table 5.Tab-delimited Table 6. istex:6F9B36B7D8E7D6ACB1F27C889FA5E4A3515AEBBF ark:/67375/WNG-B419JTVT-R ArticleID:2010JD015313 ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
ISSN:	0148-0227 2169-897X 2156-2202 2169-8996
DOI:	10.1029/2010JD015313