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Climate change impact assessment on the hydrology of a large river basin in Ethiopia using a local-scale climate modelling approach

Climate change impact assessment on the hydrology of a large river basin in Ethiopia using a local-scale climate modelling approach
Climate change impact assessment on the hydrology of a large river basin in Ethiopia using a local-scale climate modelling approach
Local-scale climate change adaptation is receiving more attention to reduce the adverse effects of climate change. The process of developing adaptation measures at local-scale (e.g., river basins) requires high-quality climate information with higher resolution. Climate projections are available at a coarser spatial resolution from Global Climate Models (GCMs) and require spatial downscaling and bias correction to drive hydrological models. We used the hybrid multiple linear regression and stochastic weather generator model (Statistical Down-Scaling Model, SDSM) to develop a location-based climate projection, equivalent to future station data, from GCMs. Meteorological data from 24 ground stations and the most accurate satellite and reanalysis products identified for the region, such as Climate Hazards Group InfraRed Precipitation with Station Data were used. The Soil Water Assessment Tool (SWAT) was used to assess the impacts of the projected climate on hydrology. Both SDSM and SWAT were calibrated and validated using the observed climate and streamflow data, respectively. Climate projection based on SDSM, in one of the large and agricultural intensive basins in Ethiopia (i.e., Awash), show high variability in precipitation but an increase in maximum (Tmax) and minimum (Tmin) temperature, which agrees with global warming. On average, the projection shows an increase in annual precipitation (>10%), Tmax (>0.4 °C), Tmin (>0.2 °C) and streamflow (>34%) in the 2020s (2011–2040), 2050s (2041–2070), and 2080s (2071–2100) under RCP2.6-RCP8.5. Although no significant trend in precipitation is found, streamflow during March–May and June–September is projected to increase throughout the 21 century by an average of more than 1.1% and 24%, respectively. However, streamflow is projected to decrease during January–February and October–November by more than 6%. Overall, considering the projected warming and changes in seasonal flow, local-scale adaptation measures to limit the impact on agriculture, water and energy sectors are required.
Awash Basin, Climate change, Climate projection, Hydro-climate modelling, Impact assessment, SDSM
0048-9697
Gebrechorkos, Solomon
ff77f8a3-b6ef-4cfd-aebd-a003bf3947a5
Bernhofer, Christian
f5193252-cd95-499f-8e1f-1fa8620649b8
Hülsmann, Stephan
7bb8b8b9-4fe3-43ee-95d2-ab7f95f44828
Gebrechorkos, Solomon
ff77f8a3-b6ef-4cfd-aebd-a003bf3947a5
Bernhofer, Christian
f5193252-cd95-499f-8e1f-1fa8620649b8
Hülsmann, Stephan
7bb8b8b9-4fe3-43ee-95d2-ab7f95f44828

Gebrechorkos, Solomon, Bernhofer, Christian and Hülsmann, Stephan (2020) Climate change impact assessment on the hydrology of a large river basin in Ethiopia using a local-scale climate modelling approach. Science of the Total Environment, 742, [140504]. (doi:10.1016/j.scitotenv.2020.140504).

Record type: Article

Abstract

Local-scale climate change adaptation is receiving more attention to reduce the adverse effects of climate change. The process of developing adaptation measures at local-scale (e.g., river basins) requires high-quality climate information with higher resolution. Climate projections are available at a coarser spatial resolution from Global Climate Models (GCMs) and require spatial downscaling and bias correction to drive hydrological models. We used the hybrid multiple linear regression and stochastic weather generator model (Statistical Down-Scaling Model, SDSM) to develop a location-based climate projection, equivalent to future station data, from GCMs. Meteorological data from 24 ground stations and the most accurate satellite and reanalysis products identified for the region, such as Climate Hazards Group InfraRed Precipitation with Station Data were used. The Soil Water Assessment Tool (SWAT) was used to assess the impacts of the projected climate on hydrology. Both SDSM and SWAT were calibrated and validated using the observed climate and streamflow data, respectively. Climate projection based on SDSM, in one of the large and agricultural intensive basins in Ethiopia (i.e., Awash), show high variability in precipitation but an increase in maximum (Tmax) and minimum (Tmin) temperature, which agrees with global warming. On average, the projection shows an increase in annual precipitation (>10%), Tmax (>0.4 °C), Tmin (>0.2 °C) and streamflow (>34%) in the 2020s (2011–2040), 2050s (2041–2070), and 2080s (2071–2100) under RCP2.6-RCP8.5. Although no significant trend in precipitation is found, streamflow during March–May and June–September is projected to increase throughout the 21 century by an average of more than 1.1% and 24%, respectively. However, streamflow is projected to decrease during January–February and October–November by more than 6%. Overall, considering the projected warming and changes in seasonal flow, local-scale adaptation measures to limit the impact on agriculture, water and energy sectors are required.

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Accepted_proof_STOTEN_140504 - Accepted Manuscript
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More information

Accepted/In Press date: 23 June 2020
Published date: 10 November 2020
Additional Information: Publisher Copyright: © 2020 Elsevier B.V.
Keywords: Awash Basin, Climate change, Climate projection, Hydro-climate modelling, Impact assessment, SDSM

Identifiers

Local EPrints ID: 442108
URI: http://eprints.soton.ac.uk/id/eprint/442108
ISSN: 0048-9697
PURE UUID: b4bf0f38-8b46-498d-9771-af19abba020a
ORCID for Solomon Gebrechorkos: ORCID iD orcid.org/0000-0001-7498-0695

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Date deposited: 07 Jul 2020 16:49
Last modified: 17 Mar 2024 05:42

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Author: Christian Bernhofer
Author: Stephan Hülsmann

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