Climate change impacts on Central Asian water resources-Reference-Cited by-同舟云学术

Climate change impacts on Central Asian water resources

Published:2012-12-13 Issue: Volume:32 Page:77-83
ISSN:1680-7359
Container-title:Advances in Geosciences
language:en
Short-container-title:Adv. Geosci.

Author:

Malsy M.,Aus der Beek T.,Eisner S.,Flörke M.

Abstract

Abstract. Central Asia is in large parts dominated by low precipitation and, consequentially, by low water availability. Therefore, changes of natural water resources induced by climate change are of high interest. The aim of this study is to analyse the potential impact of climate change on Central Asian water resources until the end of the 21st century and to point out the main affected regions. Thus, simulations with the large-scale hydrology model WaterGAP3 for the baseline and scenario periods were performed with outputs from three General Circulation Models (GCMs: ECHAM5, IPSL-CM4, and CNRM-CM3) and two IPCC-SRES emission scenarios (A2 and B1). The results show that mean modelled annual water availability increases for all scenarios and GCMs while CNRM-CM3 induces the wettest water situation for the 2085s and ECHAM5 the lowest water availability. Furthermore, robust trends to wetter or dryer conditions could be found for many basins. A seasonal shift of mean modelled water availability could be derived for ECHAM5 which does not show a second peak during summer. The application of daily input data showed no improvement of modelled monthly river discharges for most Central Asian basins compared to monthly input data.

Publisher

Copernicus GmbH

Link

https://adgeo.copernicus.org/articles/32/77/2012/adgeo-32-77-2012.pdf

Reference32 articles.

1. Alcamo, J. M., Döll, P., Henrichs, T., Kaspar, F., Lehner, B., Rösch, T., and Siebert, S.: Development and testing of the WaterGAP2 global model of water use and availability, Hydrolog. Sci. J., 48, 317–337, 2003.

2. aus der Beek, T., Flörke, M., Lapola, D. M., Schaldach, R., Voß, F., and Teichert, E.: Modelling historical and current irrigation water demand on the continental scale: Europe, Adv. Geosci., 27, 79–85, https://doi.org/http://dx.doi.org/10.5194/adgeo-27-79-201010.5194/adgeo-27-79-2010, 2010.

3. aus der Beek, T., Voß, F., and Flörke, M.: Modelling the impact of Global Change on the hydrological system of the Aral Sea basin, Phys. Chem. Earth, 36, 684–695, 2011.

4. Batimaa, P., Myagmarjav, B., Batnasan, N., Jadambaa, N., and Khishigsuren, P.: Urban water vulnerability to climate change in Mongolia. Ministry of Nature, Environment and Tourism, Water Authority, Ulaanbaatar, 78~pp., 2011.

5. Bucknall, J., Klytchnikova, I., Lampietti, J., Lundell, M., Scatasta, M., and Thurman, M.: Irrigation in Central Asia: Social, Economic and Environmental Considerations, World Bank report, 104~pp., 2003.

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