Spatial Extent of Future Changes in the Hydrologic Cycle
Components in Ganga Basin using Ranked CORDEX RCMs

Anand, Jatin; Devak, Manjula; Gosain, A. K.; Khosa, Rakesh; Dhanya, C. T.

doi:10.5194/hess-2017-189

Cited by 5 publications

(1 citation statement)

References 31 publications

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“…However, over the last decade, this model has been frequently used to investigate climate change impacts on agro-hydrological systems. This is usually done by using meteorological time series from downscaled future predictions of GCMs (e.g., Reference [19]) or RCMs [32,33], including ones from the CORDEX project, as climate drivers of the SWAT model. The SWAT simulates various components of the hydrological cycle, i.e., the surface runoff, percolation, lateral subsurface flow, channel transmission losses, evapotranspiration, and groundwater return flow.…”

Section: General Description Of Swat Modelmentioning

confidence: 99%

Sustainability Assessment of the Water Management System for the Boukan Dam, Iran, Using CORDEX- South Asia Climate Projections

Emami

Koch

2018

Water

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The present study aimed to quantify the future sustainability of a water supply system using dynamically-downscaled regional climate models (RCMs), produced in the South Asia Coordinated Regional Downscaling Experiment (CORDEX) framework. The case study is the Boukan dam, located on the Zarrine River (ZR) of Urmia’s drying lake basin, Iran. Different CORDEX- models were evaluated for model performance in predicting the temperatures and precipitation in the ZR basin (ZRB). The climate output of the most suitable climate model under the RCP45 and RCP85 scenarios was then bias-corrected for three 19-year-long future periods (2030, 2050, and 2080), and employed as input to the Soil and Water Assessment Tool (SWAT) river basin hydrologic model to simulate future Boukan reservoir inflows. Subsequently, the reservoir operation/water demands in the ZRB were modeled using the MODSIM water management tool for two water demand scenarios, i.e., WDcurrent and WDrecom, which represent the current and the more sustainable water demand scenarios, respectively. The reliability of the dam’s water supply for different water uses in the study area was then investigated by computing the supply/demand ratio (SDR). The results showed that, although the SDRs for the WDrecom were generally higher than that of the WDcurrent, the SDRs were all <1, i.e., future water deficits still prevailed. Finally, the performance of the water supply system was evaluated by means of risk, reliability, resiliency, vulnerability, and maximum deficit indices, and the combination of the indices to estimate the Sustainability Group Index (SGI). The findings indicated that, compared to the historical period for both the water demand scenarios, WDcurrent and WDrecom, the average SGI of each RCP would be decreased significantly, particularly, for the more extreme RCP85 scenario. However, as expected, the SGI decrease for the WDrecom was less than that of the WDcurrent, indicating the advantage of implementing this more sustainable water demand scenario.

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Section: General Description Of Swat Modelmentioning

confidence: 99%