Abstract
This paper addresses this issue of distinguishing the impact of climate change and human activities on streamflow using data from the Zarrinehrood River basin in Iran. The research was carried out in three main steps. First, considering the mean annual precipitation and potential evapotranspiration as the main climatic parameters, the impacts of climate change and human activities on streamflow were evaluated during the historical period. Then, an approach to naturalize the historical streamflow was proposed, based on agricultural land use changes. Finally, the future trends in temperature, precipitation, and streamflow were projected for 2015–2100 period under three climate change scenarios. The results clearly show that in the study area, human activities have more impacts on the streamflow variations compared to the climate change. It was found that the human activities and especially agricultural land developments caused 21% decrease on the annual streamflow during the historical period. Considering the naturalized and observed streamflow, the changes in the climatic parameters would cause a decrease in the streamflow by nearly 8 to 23% and 14 to 44% during 2015–2100 under the three scenarios. Moreover, when compared to the historical naturalized streamflow, the reduction in future observed flow will be in a warning rate of 28 to 53%. Finally, the share of climate change in future flow reduction was found to be between 29 and 44%, while for the human activities, it is between 56 and 16% emphasizing the importance of reconsidering the trend of current agricultural developments in the area.
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Data availability
The data that support the findings of this study belong to the Ministry of Energy of Iran, and restrictions apply to the availability of these data, which were used under license for the current study, and so are not publicly available. Data are however available from the authors upon reasonable request and with permission of the Ministry of Energy.
References
Adhikari R, Agrawal R (2013) An introductory study on time series modeling and forecasting arXiv preprint. arXiv:13026613
Allen RG, Pereira LS, Raes D, Smith M (1998) FAO irrigation and drainage paper No. 56, vol 56. Food and Agriculture Organization of the United Nations, Rome, pp 97–156
Ashofteh P-S, Bozorg-Haddad O, Loáiciga HA, Mariño MA (2016) Evaluation of the impacts of climate variability and human activity on streamflow at the basin scale. J Irrig Drain Eng:04016028
Baede A, Ahlonsou E, Ding Y, Schimel D (2001) The climate system: an overview. In: Climate change 2001: impacts, adaptation and vulnerability. Cambridge University press, pp 87–98
Borges Júnior J, Anjos RJ, Silva TJ, Lima JR, Andrade CL (2012) Métodos de estimativa da evapotranspiração de referência diária para a microrregião de Garanhuns. PE Embrapa Milho e Sorgo-Artigo em periódico indexado (ALICE)
Budyko M (1974) Climate and life, 508 pp. Academic Press, New York
Chylek P, Li J, Dubey M, Wang M, Lesins G (2011) Observed and model simulated 20th century Arctic temperature variability: Canadian earth system model CanESM2 Atmospheric Chemistry and Physics Discussions:22893–22907
Dariane AB, Karami F (2014) Deriving hedging rules of multi-reservoir system by online evolving neural networks. Water Resour Manag 28:3651–3665
Dey P, Mishra A (2017) Separating the impacts of climate change and human activities on streamflow: A review of methodologies and critical assumptions. J Hydrol 548:278–290
Dooge J, Bruen M, Parmentier B (1999) A simple model for estimating the sensitivity of runoff to long-term changes in precipitation without a change in vegetation. Adv Water Resour 23:153–163
Eamen L, Dariane A Estimating (2013) agricultural water consumption impacts on water level fluctuations of Urmia Lake, Iran. In: International Conference on Civil Engineering, Architecture & Urban Sustainable Development, Tabriz, Iran
Faramarzi N (2012) Agricultural water use in Lake Urmia basin, Iran: an approach to adaptive policies and transition to sustainable irrigation water use
Feyissa G, Zeleke G, Bewket W, Gebremariam E (2018) Downscaling of future temperature and precipitation extremes in Addis Ababa under climate change. Climate 6:58
Green TR, Taniguchi M, Kooi H (2007) Potential impacts of climate change and human activity on subsurface water resources. Vadose Zone J 6:531–532
Grizzetti B, Lanzanova D, Liquete C, Reynaud A, Cardoso A (2016) Assessing water ecosystem services for water resource management. Environ Sci Pol 61:194–203
Guo Y, Li Z, Amo-Boateng M, Deng P, Huang P (2014) Quantitative assessment of the impact of climate variability and human activities on runoff changes for the upper reaches of Weihe River. Stochastic environmental research and risk assessment 28:333–346
Hallett J (2002) Climate change 2001: the scientific basis. Edited by JT Houghton, Y. Ding, DJ Griggs, N. Noguer, PJ van der Linden, D. Xiaosu, K. Maskell and CA Johnson. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change, Cambridge University Press, Cambridge. 2001. 881 pp. ISBN 0521 01495 6 Quarterly Journal of the Royal Meteorological Society: A journal of the atmospheric sciences, applied meteorology and physical oceanography 128:1038–1039
Hargreaves GH, Samani ZA (1985) Reference crop evapotranspiration from temperature. Appl Eng Agric 1:96–99
Hassanzadeh E, Zarghami M, Hassanzadeh Y (2012) Determining the main factors in declining the Urmia Lake level by using system dynamics modeling. Water Resour Manag 26:129–145
Hulme M, Barrow EM, Arnell NW, Harrison PA, Johns TC, Downing TE (1999) Relative impacts of human-induced climate change and natural climate variability. Nature 397:688
Irwin S, Srivastav R, Simonovic S (2014) Instruction for Watershed Delineation in an Arc-GIS Environment for Regionalization Studies Department of Civil and Environmental Engineering, Western University, Canada 978-970
Jalili S, Kirchner I, Livingstone DM, Morid S (2012) The influence of large-scale atmospheric circulation weather types on variations in the water level of Lake Urmia. Iran Int J Climatol 32:1990–1996
Jiang C, Wang F (2016) Temporal changes of streamflow and its causes in the Liao River basin over the period of 1953–2011, northeastern China. Catena 145:227–238
Johnson S, Coppock R, Council NR (2004) Direct and indirect human contributions to terrestrial carbon fluxes: a workshop summary. National Academies Press
Johnston K, Ver Hoef JM, Krivoruchko K, Lucas N (2001) Using ArcGIS geostatistical analyst vol 380. Esri Redlands
Karami F, Dariane AB (2018) Many-objective multi-scenario algorithm for optimal reservoir operation under future uncertainties. Water Resour Manag:1–16
Kircher JE, Choquette AF, Richter BD (1985) Estimation of natural streamflow characteristics in western Colorado, vol 85-4086. US Geological Survey
Kustu MD, Fan Y, Rodell M (2011) Possible link between irrigation in the US High Plains and increased summer streamflow in the Midwest. Water Resour Res:47
Lee S, Yeo I-Y, Sadeghi AM, McCarty GW, Hively WD, Lang MW, Sharifi A (2018) Comparative analyses of hydrological responses of two adjacent watersheds to climate variability and change using the SWAT model. Hydrol Earth Syst Sci 22:689
Li LJ et al (2007) Assessing the impact of climate variability and human activities on streamflow from the Wuding River basin in China. Hydrological Processes: An International Journal 21:3485–3491
Liang K, Liu C, Liu X, Song X (2013) Impacts of climate variability and human activity on streamflow decrease in a sediment concentrated region in the Middle Yellow River. Stoch Env Res Risk A 27:1741–1749
Ma Z, Kang S, Zhang L, Tong L, Su X (2008) Analysis of impacts of climate variability and human activity on streamflow for a river basin in arid region of northwest China. J Hydrol 352:239–249
Mearns LO, Gutowski W, Jones R, Leung R, McGinnis S, Nunes A, Qian Y (2009) A regional climate change assessment program for North America. EOS Trans Am Geophys Union 90:311–311
Miao C, Yang L, Liu B, Gao Y, Li S (2011) Streamflow changes and its influencing factors in the mainstream of the Songhua River basin, Northeast China over the past 50 years. Environ Earth Sci 63:489–499
Milly P, Dunne K (2002) Macroscale water fluxes 2. Water and energy supply control of their interannual variability. Water Resour Res 38:24–21–24-29
Nash JE, Sutcliffe JV (1970) River flow forecasting through conceptual models part I—a discussion of principles. J Hydrol 10:282–290
Nilsson P, Uvo CB, Berndtsson R (2006) Monthly runoff simulation: comparing and combining conceptual and neural network models. J Hydrol 321:344–363
Pettitt A (1979) A non-parametric approach to the change-point problem. Appl Stat:126–135
Ping X, Guangcai C, De L (2005) Comprehensive diagnosis method of hydrologic time series change-point analysis. Hydroelectric Energy 23:11–14
Poff NL et al (2010) The ecological limits of hydrologic alteration (ELOHA): a new framework for developing regional environmental flow standards. Freshw Biol 55:147–170
Sanikhani H, Kisi O, Amirataee B (2017) Impact of climate change on runoff in Lake Urmia basin. Iran Theor Appl Climatol 1–12
Serrano A, Mateos V, Garcia J (1999) Trend analysis of monthly precipitation over the Iberian Peninsula for the period 1921–1995. Physics and Chemistry of the Earth, Part B: Hydrology, Oceans and Atmosphere 24:85–90
Shadkam S, Ludwig F, van Oel P, Kirmit Ç, Kabat P (2016) Impacts of climate change and water resources development on the declining inflow into Iran's Urmia Lake. J Great Lakes Res 42:942–952
Shen S, Song C, Cheng C, Ye S (2020) The coupling impact of climate change on streamflow complexity in the headwater area of the northeastern Tibetan Plateau across multiple timescales. J Hydrol 124996
Thornthwaite CW (1948) An approach toward a rational classification of climate. Geogr Rev 38:55–94
Trenberth KE, Miller K, Mearns L, Rhodes S (2000) Effects of changing climate on weather and human activities. University Science Books Sausalito, CA
UNEP G (2012) The drying of Iran's Lake Urmia and its environmental consequences. J Environ Dev 2:128–137
Vörösmarty CJ, Green P, Salisbury J, Lammers RB (2000) Global water resources: vulnerability from climate change and population growth science 289:284–288
Wang D, Hejazi M (2011) Quantifying the relative contribution of the climate and direct human impacts on mean annual streamflow in the contiguous United States. Water Resour Res:47
Wang J, Ishidaira H, Xu Z (2012) Effects of climate change and human activities on inflow into the Hoabinh Reservoir in the Red River basin. Procedia Environ Sci 13:1688–1698
Wilby RL, Dawson CW, Barrow EM (2002) SDSM—a decision support tool for the assessment of regional climate change impacts. Environ Model Softw 17:145–157
Wu L et al (2017) Quantitative assessment of the impacts of climate change and human activities on runoff change in a typical karst watershed, SW China. Sci Total Environ 601:1449–1465
Xin Z, Li Y, Zhang L, Ding W, Ye L, Wu J, Zhang C (2019) Quantifying the relative contribution of climate and human impacts on seasonal streamflow. J Hydrol 574:936–945
Ye X, Zhang Q, Liu J, Li X, Xu C-y (2013) Distinguishing the relative impacts of climate change and human activities on variation of streamflow in the Poyang Lake catchment, China. J Hydrol 494:83–95
Yuan Y et al (2016) Quantitative assessment of the contribution of climate variability and human activity to streamflow alteration in Dongting Lake, China. Hydrol Process
Zhan C, Niu C, Song X, Xu C (2013) The impacts of climate variability and human activities on streamflow in Bai River basin, northern China. Hydrol Res 44:875–885
Zhang L, Dawes W, Walker G (2001) Response of mean annual evapotranspiration to vegetation changes at catchment scale. Water Resour Res 37:701–708
Zhang Y, Guan D, Jin C, Wang A, Wu J, Yuan F (2011) Analysis of impacts of climate variability and human activity on streamflow for a river basin in Northeast China. J Hydrol 410:239–247
Zhang D, Liu X, Liu C, Bai P (2013) Responses of runoff to climatic variation and human activities in the Fenhe River, China. Stochastic environmental research and risk assessment 27:1293–1301
Zhang K, Ruben GB, Li X, Li Z, Yu Z, Xia J, Dong Z (2020) A comprehensive assessment framework for quantifying climatic and anthropogenic contributions to streamflow changes: A case study in a typical semi-arid North China basin. Environ Modell Softw 104704
Zhao G, Tian P, Mu X, Jiao J, Wang F, Gao P (2014) Quantifying the impact of climate variability and human activities on streamflow in the middle reaches of the Yellow River basin, China. J Hydrol 519:387–398
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Dariane, A.B., Pouryafar, E. Quantifying and projection of the relative impacts of climate change and direct human activities on streamflow fluctuations. Climatic Change 165, 34 (2021). https://doi.org/10.1007/s10584-021-03060-w
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DOI: https://doi.org/10.1007/s10584-021-03060-w