Flow regime change in an endorheic basin in southern Ethiopia

Worku, F. F.; Werner, Micha; Wright, Nigel; Zaag, Pieter van der; Demissie, Solomon S.

doi:10.5194/hess-18-3837-2014

Cited by 17 publications

(12 citation statements)

References 62 publications

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“…Land cover conversions such as from natural vegetation to cropland and settlement are generally assumed to enhance total and peak flow volumes (Legesse et al 2010). However, this assumption was not supported by empirical data particularly for large-sized watersheds in Ethiopia (Gebrehiwot et al 2014;Worku et al 2014). Thus, we found it difficult to explain the increasing signals that we found for Qann, Qwet, and high-flow indicators (Qmax1day, Qmax7day, and Qmax30day) with land cover conversations.…”

Section: Discussioncontrasting

confidence: 55%

“…Findings in our study are generally different from previous research works (Bewket and Sterk 2005;Melesse et al 2009;Tesemma et al 2010;Rientjes et al 2011;Gebrehiwot et al 2014) that reported no significant changes for annual, wet season and high-flow magnitudes and downward trends for low-flow magnitudes, particularly in the upper Abbay River Basin. However, there are some recent studies (Worku et al 2014;Degefu and Bewket 2017) that found evidences of upward changes in dry weather flow and extreme lowflow magnitudes. Another study (Berahanu et al 2014) had also reported decreasing changes in the mean zero flow days and coefficient of variation in streamflow magnitudes for Ethiopian rivers.…”

Section: Discussionmentioning

confidence: 99%

“…Mixed and opposite trend signals also observed between adjacent gauging stations in the same and neighboring river basins. The observed complex trend signals between adjust streamflow stations may be attributed to the presence of very complex climate, topography, land cover, and land use systems that showed greater variation with short horizontal distances over the highland part of the country (Bewket and Conway 2007;Bewket 2014, 2017;Gebrehiwot et al 2014;Worku et al 2014).…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies were focused on Abbay (Blue Nile) River Basin and its sub-catchments (Bewket and Sterk 2005;Melesse et al 2009;Tesemma et al 2010;Rientjes et al 2011;Gebrehiwot et al 2014) and a few on Omo-Ghibe River Basin (Worku et al 2014;Degefu and Bewket 2017). These studies reported the absence of systematic trends in mean annual, mean seasonal, and extreme hydrological flow magnitudes, except Worku et al (2014) and Degefu and Bewket (2017) who reported that there was a tendency towards upward change in low-flow indices. The aim of this study is therefore to provide a more comprehensive analysis of trends in streamflow amount and hydrological extremes for a large number of watersheds across the Ethiopian highlands.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Detection of trends in hydrological extremes for Ethiopian watersheds, 1975–2010

et al. 2019

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This study investigates trends in streamflow variables for 57 gauging stations distributed across the Ethiopian highlands for the period 1975-2010. We used the Mann-Kendall's test to detect trends and the Sen's slope estimator to calculate trend magnitudes. The findings show that more than 70% out of 513 test cases have shown increasing signals, and 32% of the tests were globally field significant at 0.05 level. Increasing change in low-flow magnitudes and decreasing change in low-flow frequency that exceeded 80 percentile (Qmin80p) were more prevalent than the others. Global field significant increasing changes were observed for 40% out of 228 test cases for low-flow amounts, while Qmin80p has shown decreasing trend at 46 out of 57 stations, and 26 of these were statistically significant. The general tendency is towards upward change, but there were some stations that showed field significant decreasing trends for high-flow indicators. General trend signals (upward or downward) and stations with significant changes did not show any spatial pattern. There were even adjacent gauging stations within the same river basin or adjacent river basins that showed statistically significant opposite trends for some test cases. The complex spatial pattern of trend signals is partly attributable to the very complex topographic, climatic, and land cover variations in the country that are well documented in previous studies. Also, the observed trends are difficult to fully explain in terms of climate change or land cover conversion. Generally, the results of this study contradict with previous studies that reported no significant trends in streamflow variables over Ethiopia. The study has important implications for climate change adaptation planning, water-related disaster risk management, and water sector development activities in the country.

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Section: Discussioncontrasting

confidence: 55%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Detection of trends in hydrological extremes for Ethiopian watersheds, 1975–2010

et al. 2019

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“…The most widely used hydrologic metrics are called indicators of hydrologic alteration (IHA), which include 33 hydrologic parameters describing a wide array of flow characteristics, including the magnitude of monthly runoff, the magnitude of annual extreme streamflow, the timing of annual extreme flow, the frequency and duration of high and low flow pulse and the rate and frequency of streamflow changes [13]. IHA metrics have been successfully applied to evaluate hydrological alterations in a suite of watersheds located in arid, semi-arid, and humid regions [14][15][16]. However, previous studies have also concluded that there is statistical redundancy in the parameters of IHA and that some parameters are inter-correlated [17,18].…”

Section: Introductionmentioning

confidence: 99%

Analyzing Changes in the Flow Regime of the Yangtze River Using the Eco-Flow Metrics and IHA Metrics

Gao

Wang

2018

Water

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Changes in the flow regime of the Yangtze River were investigated using an efficient framework that combined the eco-flow metrics (ecosurplus and ecodeficit) and Indicators of Hydrologic Alteration (IHA) metrics. A distributed hydrological model was used to simulate the natural flow regime and quantitatively separate the impacts of reservoir operation and climate variation on flow regime changes. The results showed that the flow regime changed significantly between the pre-dam and post-dam periods in the main channel and major tributaries. Autumn streamflow significantly decreased in the main channel and in the tributaries of the upper Yangtze River, as a result of a precipitation decrease and reservoir water storage. The release of water from reservoirs to support flood regulation resulted in a significant increase in winter streamflow in the main channel and in the Minjiang, Wujiang, and Hanjiang tributaries. Reservoir operation and climate variation caused a significant reduction in low flow pulse duration in the middle reach of the Yangtze River. Reservoir operation also led to an increase in the frequency of low flow pulses, an increase in the frequency of flow variation and a decrease in the rate of rising flow in most of the tributaries. An earlier annual minimum flow date was detected in the middle and lower reaches of the Yangtze River due to reservoir operation. This study provides a methodology that can be implemented to assess flow regime changes caused by dam construction in other large catchments.

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Hydrological Cycle in the Heihe River Basin and Its Implication for Water Resource Management in Endorheic Basins

et al. 2018

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Endorheic basins around the world are suffering from water and ecosystem crisis. To pursue sustainable development, quantifying the hydrological cycle is fundamentally important. However, knowledge gaps exist in how climate change and human activities influence the hydrological cycle in endorheic basins. We used an integrated ecohydrological model, in combination with systematic observations, to analyze the hydrological cycle in the Heihe River Basin, a typical endorheic basin in arid region of China. The water budget was closed for different landscapes, river channel sections, and irrigation districts of the basin from 2001 to 2012. The results showed that climate warming, which has led to greater precipitation, snowmelt, glacier melt, and runoff, is a favorable factor in alleviating water scarcity. Human activities, including ecological water diversion, cropland expansion, and groundwater overexploitation, have both positive and negative effects. The natural oasis ecosystem has been restored considerably, but the overuse of water in midstream and the use of environmental flow for agriculture in downstream have exacerbated the water stress, resulting in unfavorable changes in surface‐ground water interactions and raising concerns regarding how to fairly allocate water resources. Our results suggest that the water resource management in the region should be adjusted to adapt to a changing hydrological cycle, cropland area must be reduced, and the abstraction of groundwater must be controlled. To foster long‐term benefits, water conflicts should be handled from a broad socioeconomic perspective. The findings can provide useful information on endorheic basins to policy makers and stakeholders around the world.

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Flow regime change in an endorheic basin in southern Ethiopia

Cited by 17 publications

References 62 publications

Detection of trends in hydrological extremes for Ethiopian watersheds, 1975–2010

Detection of trends in hydrological extremes for Ethiopian watersheds, 1975–2010

Analyzing Changes in the Flow Regime of the Yangtze River Using the Eco-Flow Metrics and IHA Metrics

Hydrological Cycle in the Heihe River Basin and Its Implication for Water Resource Management in Endorheic Basins

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