[1]. Niyazi BA, Masoud MH, Ahmed M, Basahi JM, Rashed MA. Runoff assessment and modeling in arid regions by integration of watershed and hydrologic models with GIS techniques. J African Earth Sci. 2020; (172): 103966. [2]. Youssef AMA, Ibrahem SMM, El Sayed AN, Masoud MHZ. Assessment and management of water resources in Wadi El-Deeb using geophysical, hydrological and GIS techniques-Red Sea. J African Earth Sci. 2020; (164): 103777.
[3]. Resende NC, Miranda JH, Cooke R, Chu ML, Chou SC. Impacts of regional climate change on the runoff and root water uptake in corn crops in Parana, Brazil. Agric Water Manag. 2019; (221): 556–565.
[4]. Rogelj J, Meinshausen M, Knutti R. Global warming under old and new scenarios using IPCC climate sensitivity range estimates. Nat Clim Chang. 2012; 2(4): 248–253.
[5]. Gao C, He Z, Pan S, Xuan W, Xu YP. Effects of climate change on peak runoff and flood levels in Qu River Basin, East China. Vol. 28, Journal of Hydro-Environment Research. 2020; (28): 34–47.
[6]. Yang Y, Weng B, Man Z, Yu Z, Zhao J. Analyzing the contributions of climate change and human activities on runoff in the Northeast Tibet Plateau. J Hydrol Reg Stud. 2020; (27): 100639.
[7]. Zhang Q, Liu J, Singh VP, Shi P, Sun P. Hydrological responses to climatic changes in the Yellow River basin, China: Climatic elasticity and streamflow prediction. J Hydrol. 2017; (554): 635–645.
[8]. Zhai R, Tao F. Contributions of climate change and human activities to runoff change in seven typical catchments across China. Sci Total Environ. 2017; 605–606: 219–229.
[9]. Walling DE, Fang D. Recent trends in the suspended sediment loads of the world’s rivers. Glob Planet Change. 2003; 39(1–2): 111–126.
[10]. Good P, Gregory JM, Lowe JA. A step-response simple climate model to reconstruct and interpret AOGCM projections. Geophys Res Lett [Internet]. 2011; 38(1): L01703.
[11]. Ahmadi M, Motamedvaziri B, Ahmadi H, Moeini A, Zehtabiyan GR. Assessment of climate change impact on surface runoff, statistical downscaling and hydrological modeling. Phys Chem Earth, Parts A/B/C. 2019; (114): 102800. 2
[12]. Xue D, Zhou J, Zhao X, Liu C, Wei W, Yang X, et al. Impacts of climate change and human activities on runoff change in a typical arid watershed, NW China. Ecol Indic. 2021; (121): 107013.
[13]. Yan X, Bao Z, Zhang J, Wang G, He R, Liu C. Quantifying contributions of climate change and local human activities to runoff decline in the upper reaches of the Luanhe River basin. J Hydro-environment Res. 2020; 28: 67–74.
[14]. Etter S, Addor N, Huss M, Finger D. Climate change impacts on future snow, ice and rain runoff in a Swiss mountain catchment using multi-dataset calibration. J Hydrol Reg Stud. 2017; 13: 222–239.
[15]. Yang W, Long D, Bai P. Impacts of future land cover and climate changes on runoff in the mostly afforested river basin in North China. J Hydrol. 2019; (570): 201–219.
[16]. Mirdashtovan, M., Malekian, A., Mohseni Saravi, M. Stream flow simulation using statistical downscaling of climatic data: Urmia Lake Basin. Iranian journal of Ecohydrology. 2018; 5(2): 419-431. [Persian].
[17]. Zarei, A., Sayari, N., Bakhtiari, B., Ahmadi, M. Modeling of Precipitation – runoff for Predicting Upcoming Flow Streams in Halilroud Basin. Iranian journal of Ecohydrology. 2021; 8(1): 143-160. [Persian].
[18]. Ghorbani Dailari, M., Darbandi, S., Asadi, E., Samadian, M. Simulation of Parameters Affecting the River Flow Trend using the IHACRES Rainfall-runoff Model in Future Periods (Case Study: Zolachai River). Iranian journal of Ecohydrology. 2021; 8(1): 177-193. [Persian].
[19]. Wang X, He K, Dong Z. Effects of climate change and human activities on runoff in the Beichuan River Basin in the northeastern Tibetan Plateau, China. CATENA. 2019; 176(1): 81–93.
[20]. Marko K, Elfeki A, Alamri N, Chaabani A. Two Dimensional Flood Inundation Modelling in Urban Areas Using WMS, HEC-RAS and GIS (Case Study in Jeddah City, Saudi Arabia). Springer International Publishing. 2019; 265–267.
[21]. Srinivas R, Singh AP, Deshmukh A. Development of a HEC-HMS-based watershed modeling system for identification, allocation, and optimization of reservoirs in a river basin. Environ Monit Assess. 2018; 190(1): 31.
[22]. Mousavi SJ, Abbaspour KC, Kamali B, Amini M, Yang H. Uncertainty-based automatic calibration of HEC-HMS model using sequential uncertainty fitting approach. J Hydroinformatics. 2012; 14(2): 286–309.
[23]. Imani T, Delghandi M, Emamgholizade S, Ganji-Noroozy Z. Estimating Floods of Various Return Periods for Babolrood Catchment Using WMS Model. Journal of rangeland and watershed. in press. [Persian].
[24]. Pichuka S, Prasad R R, Maity R, Kunstmann H. Development of a method to identify change in the pattern of extreme streamflow events in future climate: Application on the Bhadra reservoir inflow in India. J Hydrol Reg Stud. 2017; 9: 236–246.
[25]. Semenov M, Stratonovitch P. Use of multi-model ensembles from global climate models for assessment of climate change impacts. Clim Res. 2010; 41(1): 1–14.
[26]. Ruiz-Ramos M, Mínguez M. Evaluating uncertainty in climate change impacts on crop productivity in the Iberian Peninsula. Clim Res. 2010; 44(1): 69–82.
[27]. Zhang X, Xu Y-P, Fu G. Uncertainties in SWAT extreme flow simulation under climate change. J Hydrol. 2014; (515): 205–222.
[28]. Bell FC. Generalized rainfall-duration-frequency relationships. J Hydraul Div. 1969; 95(1): 311–327.
[30]. Alizadeh A. Principles of applied hydrology. 29th ed. Imam Reza; 2010. [Persian].
[31]. Pani EA, Haragan DR. A comparison of Texas and Illinois Temporal Rainfall Distributions. 4th Conference on Hydrometeorology, American Meteorology Society, Boston, USA. 1981; 76-80.
[32]. Hlavčová K, Štefunková Z, Valent P, Kohnová S, Výleta R, Szolgay J. Modelling the Climate Change Impact On Monthly Runoff in Central Slovakia. Procedia Eng. 2016; 161: 2127–2132.
[33]. Sarkar S, Maity R. Increase in probable maximum precipitation in a changing climate over India. J Hydrol. 2020; (585): 124806.