Climate change in the Blue Nile Basin Ethiopia: implications for water resources and sediment transport

As much as 66% of the Nile River flow that reaches Egypt originates in the Highlands of the Ethiopian Blue Nile Basin (BNB). This imbalance in water availability poses a threat to water security in the region and could be impacted by climate change. This study coupled a watershed model analysis with...

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Bibliographic Details
Published in:Climatic change 2016-11, Vol.139 (2), p.229-243
Main Authors: Wagena, Moges B., Sommerlot, Andrew, Abiy, Anteneh Z., Collick, Amy S., Langan, Simon, Fuka, Daniel R., Easton, Zachary M.
Format: Article
Language:English
Subjects:
Agricultural production
Agriculture
Analysis
Atmospheric Sciences
Availability
Basins
Bias
Climate
Climate change
Climate Change/Climate Change Impacts
Climate models
Climate prediction
Climatic data
Earth and Environmental Science
Earth Sciences
Environmental impact
Freshwater
Greenhouse effect
Hydroelectric power
Impact analysis
Intergovernmental Panel on Climate Change
Internet resources
Irrigation
Mathematical models
Precipitation
Productivity
River flow
Sea level
Seasons
Sediment transport
Sediments
Soil erosion
Stream discharge
Stream flow
Studies
Water
Water availability
Water resources
Water security
Watersheds
Wind
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Summary:As much as 66% of the Nile River flow that reaches Egypt originates in the Highlands of the Ethiopian Blue Nile Basin (BNB). This imbalance in water availability poses a threat to water security in the region and could be impacted by climate change. This study coupled a watershed model analysis with bias corrected and downscaled Intergovernmental Panel on Climate Change (IPCC) Coupled Model Intercomparison Project 5 (CMIP5) climate data to assess the potential impact of climate change on water resources and sediment dynamics in two critical headwater basins of the BNB. Climate scenarios analyzed include RCP2.6, RCP4.5, RCP6.0, and RCP8.5 from six climate models, which were used to force watershed models calibrated against historic streamflow for six gauged sub-watersheds in the Tana basin and four gauged sub-watersheds in the Beles basin. We developed distributed watershed model parameter estimates from the gauged sub-watersheds, which were applied to un-gauged portions of the basins using topographically informed parameter transfer functions. We analyzed the impact of climate change for two future time periods (2041–2065 and 2075–2099) by running each of the six downscaled and bias corrected CMIP5 model predicted climate forcings through the watershed models to assess the impact of ensemble model mean and variance in climate change prediction on water availability and sediment transport. Results indicate that the Tana and Beles basins will experience increases both in mean annual flow (22-27%) and sediment concentrations (16-19%). Interestingly, and of significance for water availability and hydropower development, the monsoon in the Tana and Beles basins will lengthen by approximately four (Tana) to six (Beles) weeks. These results highlight both the considerable variance in climate change impacts as well as the potential for beneficial outcomes in the region.
ISSN:0165-0009
1573-1480
DOI:10.1007/s10584-016-1785-z