| Title: | Hydrological response of watershed to historical and future land use land cover change dynamics of Nashe Watershed, Ethiopia |
| Authors: | Leta, M.K., T.A. Demissie and J. Tränckner |
| Year: | 2021 |
| Journal: | Water |
| Volume (Issue): | 13(17) |
| Pages: | |
| Article ID: | 2372 |
| DOI: | 10.3390/w13172372 |
| URL (non-DOI journals): | |
| Model: | SWAT |
| Broad Application Category: | hydrologic only |
| Primary Application Category: | land use change assessment |
| Secondary Application Category: | water balance assessment |
| Watershed Description: | 945.78 km^2 Nashe River, which is administratively part of the Abay Chomen and Horo Woredas and is a tributary of the Blue Nile River located in the State of Oromia in northwest Ethiopia. |
| Calibration Summary: | |
| Validation Summary: | |
| General Comments: | |
| Abstract: | Land use land cover (LULC) change is the crucial driving force that affects the hydrological processes of a watershed. The changes of LULC have an important influence and are the main factor for monitoring the water balances. The assessment of LULC change is indispensable for sustainable development of land and water resources. Understanding the watershed responses to environmental changes and impacts of LULC classes on hydrological components is vigorous for planning water resources, land resource utilization, and hydrological balance sustaining. In this study, LULC effects on hydrological parameters of the Nashe watershed, Blue Nile River Basin are investigated. For this, historical and future LULC change scenarios in the Nashe watershed are implemented into a calibrated Soil and Water Assessment Tool (SWAT) model. Five LULC scenarios have been developed that represent baseline, current, and future periods corresponding to the map of 1990, 2005, 2019, 2035, and 2050. The predicted increase of agricultural and urban land by decreasing mainly forest land will lead till 2035 to an increase of 2.33% in surface runoff and a decline in ground water flow, lateral flow, and evapotranspiration. Between 2035 and 2050, a gradual increase of grass land and range land could mitigate the undesired tendency. The applied combination of LULC prognosis with process-based hydrologic modeling provide valuable data about the current and future understanding of variation in hydrological parameters and assist concerned bodies to improve land and water management in formulating approaches to minimize the conceivable increment of surface runoff. |
| Language: | English |
| Keywords: | hydrologic response; LULC change; surface runoff; SWAT model; water balance |