Abstract
Finer climate change information on spatial scale is required for impact studies than that presently provided by global or regional climate models. It is especially true for regions like South Asia with complex topography, coastal or island locations, and the areas of highly heterogeneous land-cover. To deal with the situation, an inexpensive method (statistical downscaling) has been adopted. Statistical DownScaling Model (SDSM) employed for downscaling of daily minimum and maximum temperature data of 44 national stations for base time (1961–1990) and then the future scenarios generated up to 2099. Observed as well as Predictors (product of National Oceanic and Atmospheric Administration) data were calibrated and tested on individual/multiple basis through linear regression. Future scenario was generated based on HadCM3 daily data for A2 and B2 story lines. The downscaled data has been tested, and it has shown a relatively strong relationship with the observed in comparison to ECHAM5 data. Generally, the southern half of the country is considered vulnerable in terms of increasing temperatures, but the results of this study projects that in future, the northern belt in particular would have a possible threat of increasing tendency in air temperature. Especially, the northern areas (hosting the third largest ice reserves after the Polar Regions), an important feeding source for Indus River, are projected to be vulnerable in terms of increasing temperatures. Consequently, not only the hydro-agricultural sector but also the environmental conditions in the area may be at risk, in future.
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Acknowledgments
The project was mainly organized by China Meteorological Administration and Pakistan Meteorological Department. Also, the study was funded by Asian Development Bank, National Basic Research Program ‘973’ of China (No. 2010CB428401), special Fund of Climate Change of the China Meteorological Administration (CCSF-09-16), and National Natural Science Foundation of China (40910177).
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Kazmi, D.H., Li, J., Rasul, G. et al. Statistical downscaling and future scenario generation of temperatures for Pakistan Region. Theor Appl Climatol 120, 341–350 (2015). https://doi.org/10.1007/s00704-014-1176-1
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DOI: https://doi.org/10.1007/s00704-014-1176-1