Prediction of Climate Change Impact on Monthly River Discharge’s Trend using IHACRES hydrological model (Case Study: Galikesh Watershed)
Subject Areas : Farm water management with the aim of improving irrigation management indicatorsخلیل قربانی 1 , الهه سهرابیان 2 , میثم سالاریجزی 3 , محمد عبدالحسینی 4
1 - Faculty member
2 - دانشآموخته کارشناسی ارشد مهندسی منابع آب
3 - عضو هیأت علمی
4 - عضو هیأت علمی
Keywords: CClimate Change, Sen Slope Test, Mann-Kendall Test, Trend analysis, River Discharge,
Abstract :
AClimate change causes change in temperature and rainfall and consequently affects river discharge. Changes in rainfall can be simulated by global circulation models under different climatic scenarios but investigations of changes in river discharge require rainfall-runoff models. The Galikesh basin as one of most flood prone basins in Gloestan Province is considered for determination of changes in river discharge under climate change effect. Temperature and rainfall is produced for future climatic period (2011-2030) based on global circulation model HADCM3, using LARS-WG data generator model. The produced data under different climatic scenario are used as inputs of calibrated IHACRES model to simulate river discharge for future climatic periods. The climate change analysis shows under different scenarios in the study area air temperature increase in different months, which a rise in warm months is more than other months of the year, but the annual precipitation decreases. The Mann-Kendall test is used to detect monotonic trend of seasonal and semiannual river discharge series. The results indicate no trend for spring and first semiannual and negative trend for other seasons and second semiannual series in 5 percent significance level.
اسدی، ا. و حیدری، ا. 1390. تحلیل تغییرات سریهای دما و بارش شیراز طی دوره 2005-1951. مجله جغرافیا و برنامهریزی محیطی. 41 (1). 42-39.
آذری، م.، مرادی، ح.ر.، ثقفیان، ب. و فرامرزی، م.1392. ارزیابی اثرات هیدرولوژیکی تغییر اقلم در حوضه آبخیز گرگانرود. نشریه آب و خاک. 27(3): 547-537.
بابائیان، ا. و نجفینیک، ز. 1385. معرفی و ارزیابی مدل LARS-WG برای مدلسازی پارامترهای هواشناسی استان خراسان، دوره آماری (2003-1961). مجله نیوار (63-62)، 30-24.
بختیاری، ب.، صاحبی، ح. و قادری، ک. 1392. کاربرد مدل WEAP و بررسی اثر تغییر اقلیم بر سیستمهای برداشت آب حوزه آبریز گرگانرود. پنجمین کنفرانس مدیریت منابع آب ایران.
بذرافشان، ج. 1388. ارزیابی ریسک خشکسالی کشاورزی و جستجوی روش مناسب برای برآورد تاثیر کمی آن بر عملکرد محصول گندم و جو. رساله دکتری هواشناسی کشاورزی. دانشگاه تهران. 253ص.
خزائی، م. 1395. ارزیابی اثر تغییر اقلیم بر رژیم هیدرولوژیکی یک حوضه آبریز کوهستانی در ایران. حفاظت منابع آب و خاک، 5 (3): 54-43.
سبزیپرور، ع.ا. و شادمانی، م. 1390. تحلیل روند تبخیر و تعرق مرجع با استفاده از آزمون من-کندال و اسپیرمن در مناطق خشک ایران. نشریه آب و خاک. 4 (25). 834-823.
سهرابیان، ا.، مفتاح هلقی، م.، قربانی، خ.، گلیان، س. و ذاکرینیا، م. 1394. بررسی تاثیر تغییر اقلیم بر آبدهی حوضه با دخالت مدل هیدرولوژی(مطالعه موردی: حوضه گالیکش در استان گلستان). نشریه پژوهشهای حفاظت آب و خاک. 2(22). 125-111.
قربانی، خ. 1394. ارزیابی مدلهای دادهکاوی در ریزمقیاس نمایی بارش بر اساس دادههای مدل گردش عمومی NCEP؛ مطالعه موردی: ایستگاه سینوپتیک کرمانشاه. مجله پژوهش آب ایران. 8 (15). 186-177.
Abbaspour, K.C., Faramarzi, M., Ghasemi, S.S. and Yang, H. 2009. Assessing the impact of climate change on water resources in Iran. Water Resources Research. 45(10): p. W10434.
Asgari, A., Rahimzade, F., Mohammadian, N. and Fattahi, E. 2008. Trend analysis of extreme precipitation indices over Iran, Iran-Water Resources Research, 3: 42-55.
Chen H. Yu Xu C. and Guo Sh. 2012. Comparison and evaluation of multiple GCMs, statistical downscaling and hydrological models in the study of climate change impacts on runoff. Journal of hydrology, 434-435: 36-45.
Croke, B.F.W., F. Andrews, J. Spate and S.M. Cuddy. 2005. IHACRES user guide.Technical Report 2005/19. Second Edition. iCAM, School of Resources,Environment and Society, The Australian National University, Canberra.http://www.toolkit.net.au/ihacres.
Dibike B. Y. and Coulibaly P. 2006. Temporal neural networks for downscaling climate variability and extremes. Journal. Neural Networks, 19: 135-144.
Ghahraman, B. 2006 Time trend in the annual temperature of Iran, Turk J. Agric, 30: 439-448.
Hamed, K.H., and Rao, A.R. 1998. A modified Mann–Kendall trend test for auto correlated data. Journal of hydrology. 204: 182–196.
Hewitson B. C. and Crane R. G. 1996. Climate downscaling: Techniques and applications. Climate Research. 7:85-95.
IPCC. 2001. Climate Change: The Scientific Basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, UK and New York, NY, USA, 881 pp.
IPCC. 2007. Summary for policy makers Climate change: The physical science basis. Contribution of working group I to the forth assessment report. Cambridge University Press, 881 PP.
Jakeman,A.J. and Hornberger,G. M.(1993),“HowMuch Complexity Is Warranted in a RainfallModel? Water resources research, 29(8): 2637-2649.
Jiang, T., Su, B. and Hartmann, H. (2007). Temporal and spatial trends of precipitation andriver flow in theYangtze RiverBasin, 1961-2000, Geomorphology, 85, 143-154.
Karamooz, M., and Araghinejad, Sh. 2005. Advanced Hydrology. Amirkabir University. Press, 464 p.
Kendall M.G. 1975. Rank correlation measures. Charles Griffin, London.
Mann H.B. 1945. Non-parametric tests against trend. Econometrica, 13, MathSci Net, pp. 245-259.
Marofi, S., Soleymani, S., Salarijazi, M., & Marofi, H. (2012). Watershed-wide trend analysis of temperature characteristics in Karun-Dez watershed, southwestern Iran. Theoretical and Applied Climatology, 110(1-2), 311-320.
Moazed, H., Salarijazi, M., Moradzadeh, M., & Soleymani, S. (2012). Changes in rainfall characteristics in Southwestern Iran. African Journal of Agricultural Research, 7(18), 2835-2843.
Muttiah R.S. and Wurbs R.A. 2002. Modeling the impacts of climate change on water supply reliabilities. WaterInternational, 27(3): p. 407-419.
Rasco, P. Szeidl, L. and Semenov, M.A. 1991. A serial approach to localstochastic models. J. Ecological Modeling 57, 27-41.
Sajjad Khan M. Coulibaly P. and Dibike Y. 2006. Uncertainty analysis of statistical downscaling methods. J. Hydrology, 319(4): 357-382.
Salarijazi, M., Akhond-Ali, A. M., Adib, A., & Daneshkhah, A. (2012). Trend and change-point detection for the annual stream-flow series of the Karun River at the Ahvaz hydrometric station. African Journal of Agricultural Research, 7(32), 4540-4552.
Semenov, M.A., 2008. Simulation of extreme weather events by a stochastic weather generator. Climate Research 35, 203-212.
Semenov, M.A., Brooks, R.J., Barrow, E.M., and Richardson, C.W. 1998. Comparison of the WGEN and LARS-WG stochastic weather generators for diverse climates. Climate Res. 10: 95-107.
Sen, P.K. 1968. Estimates of the regression coefficients based on Kendall’s tau. Journal of the American Statistical Association. 63: 1379–1389.
Steele- Dunne, S., Lynch, P., McGrath, R., Semmler, T., Wang, Sh., Hanafin, J. and Nolan, P. (2008): The impactsof climate change on hydrology in Ireland. Journal of Hydrology, 356: 28-45.
Tabari H., Marofi S., Aeini A., HosseinzadehTalaeea P., and Mohammadi K. 2011. Trend analysis of reference evapotranspiration in the western half of Iran, Agr. Forest Meteorol, 151 (2): 128-136.
Williams, J.R., 1991. Runoff and soil erosion. In: Hanks, R.J., Ritchie, J.T. (Eds.) Modeling Plant and Soil Systems. Agronomy Monograph No. 31, pp. 439-456.
Zhang, X., Vincent, L. A., Hogg, W.D., and Niitsoo, A. 2000. Temperature andrainfall trends in Canadaduring the 20th century. Atmospheric Ocean. 38: 395-429.