Recent changes in rainfall and rainy days in Ethiopia

Seleshi, Yilma; Zanke, Ulrich

doi:10.1002/joc.1052

Cited by 484 publications

(445 citation statements)

References 10 publications

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“…The first and most common is the annual-maximum (AM) method, which samples the largest streamflow in each year. The second method is the peaks-over-threshold (POT) method (Smith, 1984(Smith, , 1987Todorovic and Zelenhasic, 1970), in which all distinct, independent dominant peak flows greater than a fixed threshold are counted. In contrast to the AM method, POT can capture multiple large independent floods within a single year, including the annual maximum flow, but may not capture the annual maximum flow in years in which streamflow is less than the pre-defined threshold; this threshold can either be defined based on a specific average number of floods or a specific mean exceedance level over the entire period (Cunderlik et al, 2004a;Institute of Hydrology, 1999;Lang et al, 1999).…”

Section: Methodology For Defining Grid-cell-scale High-flow Seasonsmentioning

confidence: 99%

“…For example, eastern Africa has two rainy seasons, the major season from June to September and the minor season from January to April/May. These two seasons are induced by northward and southward shifts of the Inter-tropical Convergence Zone (ITCZ) (Seleshi and Zanke, 2004). This bi-modal eastern African pattern allows for potential flooding in either season.…”

Section: Defining Minor High-flow Seasonsmentioning

confidence: 99%

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Defining high-flow seasons using temporal streamflow patterns from a global model

Lee

Ward

Block

2015

Hydrol. Earth Syst. Sci.

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Abstract. Globally, flood catastrophes lead all natural hazards in terms of impacts on society, causing billions of dollars of damages annually. Here, a novel approach to defining high-flow seasons (3-month) globally is presented by identifying temporal patterns of streamflow. The main high-flow season is identified using a volume-based threshold technique and the PCR-GLOBWB model. In comparison with observations, 40 % (50 %) of locations at a station (subbasin) scale have identical peak months and 81 % (89 %) are within 1 month, indicating fair agreement between modeled and observed high-flow seasons. Minor high-flow seasons are also defined for bi-modal flow regimes. Identified major and minor high-flow seasons together are found to well represent actual flood records from the Dartmouth Flood Observatory, further substantiating the model's ability to reproduce the appropriate high-flow season. These high-spatial-resolution high-flow seasons and associated performance metrics allow for an improved understanding of temporal characterization of streamflow and flood potential, causation, and management. This is especially attractive for regions with limited observations and/or little capacity to develop early warning flood systems.

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Section: Methodology For Defining Grid-cell-scale High-flow Seasonsmentioning

confidence: 99%

Section: Defining Minor High-flow Seasonsmentioning

confidence: 99%

Defining high-flow seasons using temporal streamflow patterns from a global model

Lee

Ward

Block

2015

Hydrol. Earth Syst. Sci.

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“…For group B, it is also shown from Table 4 that influences also are obtained from Niño 3, the Indian Ocean and as far as the extra-tropical Southern Hemisphere. The annual rainfall in Sudan and Ethiopia (group B) has been shown in a number of studies to be influenced by the El Niño-Southern Oscillation (ENSO); see Osman and Shamseldin (2002) for Sudan; Fontaine and Janicot (1992), and Grist and Nicholson (2001) for the Sahel belt; Abtew et al (2009), Beltrando andCamberlin (1993), Diro et al (2010), Korecha and Barnston (2007), Seleshi and Demarée (1995), Segele and Lamb (2005), and Seleshi and Zanke (2004) for Ethiopia.…”

Section: Identification Of Drivers For the Rainfall Variabilitymentioning

confidence: 99%

Spatial and temporal variability of rainfall in the Nile Basin

Onyutha

Willems

2015

Hydrol. Earth Syst. Sci.

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Abstract. Spatiotemporal variability in annual and seasonal rainfall totals were assessed at 37 locations of the Nile Basin in Africa using quantile perturbation method (QPM). To get insight into the spatial difference in rainfall statistics, the stations were grouped based on the pattern of the long-term mean (LTM) of monthly rainfall and that of temporal variability. To find the origin of the driving forces for the temporal variability in rainfall, correlation analyses were carried out using global monthly sea level pressure (SLP) and sea surface temperature

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“…The authors noted that improvements in understanding the basic circulation patterns across Africa are essential for improving the management of socio-economic activities affected by climate variability and future climate change, not only in Africa but also on a more global scale. Because the large-scale atmospheric circulation is directly linked to many aspects of regional climate variation (Beck et al, 2007), investigation of the links between atmospheric circulation patterns over Africa and rainfall there and elsewhere is important for understanding For example, although the large-scale circulation systems during the Indian summer (south-west) monsoon generally are associated with concurrent rainfall over the Horn of Africa (Krishnamurti and Bhalme, 1976;Conway, 2000;Gissila et al, 2004;Seleshi and Zanke, 2004;Korecha and Barnston, 2007), only a few quantitative studies have linked those circulation systems specifically to local weather and climate patterns over the Horn of Africa (e.g. Beltrando and Camberlin, 1993;Camberlin, 1997;Shanko and Camberlin, 1998;Block and Rajagopalan, 2007).…”

Section: Introductionmentioning

confidence: 99%

Large‐scale atmospheric circulation and global sea surface temperature associations with Horn of Africa June–September rainfall

Segele

Lamb

Leslie

2008

Intl Journal of Climatology

143

171

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This study uses correlation, regression, and composite analyses for the period 1970-1999 to explore the relationships between the June-September rainfall in the Horn of Africa (especially Ethiopian) and large-scale regional atmospheric circulation patterns across Africa and the Atlantic and Indian Oceans, and global sea surface temperature (SST) anomalies. Abundant rainfall in the Horn of Africa is associated with enhanced westerlies across western and central Africa. These westerlies are produced by a stronger north-east directed mean sea level pressure (MSLP) gradient resulting from MSLP intensification over the Gulf of Guinea and deepening of the monsoon trough across the Arabian Peninsula. This is reflected by a strong correlation (−0.71) between 5-day (pentad) Ethiopian rainfall and the Gulf of Guinea minus the Arabian Peninsula MSLP difference. This correlation decreases to −0.39 when the seasonal cycles are removed from both time series. A wet Horn of Africa monsoon is also associated with deep moist air extending up to mid-troposphere and large water vapour transport convergence across much of Ethiopia, a strong Somali low-level jet, and a strong tropical easterly jet (TEJ). Although there are large changes in TEJ strength, the position of the jet axis shows little variation between wet and dry events. Associated with the TEJ, the strongest upper level divergence occurs at 100 hPa, where the raw/de-seasonalized zonal wind speed correlates negatively (−0.71/−0.23) with the corresponding Ethiopian rainfall at the pentad time-scale. Furthermore, SSTs over the equatorial Pacific, Indian, and southern Atlantic Oceans correlate strongly with contemporary Ethiopian summer rainfall. In general, Ethiopian rainfall is suppressed during El Niño and enhanced during La Niña. This identification and documentation of the regional atmospheric circulation patterns and global SST anomalies directly linked to rainfall variability over Ethiopia/Horn of Africa, are crucial for developing statistical prediction schemes and designing climate model simulations for the region on intra-seasonal to inter-annual time-scales.

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Recent changes in rainfall and rainy days in Ethiopia

Cited by 484 publications

References 10 publications

Defining high-flow seasons using temporal streamflow patterns from a global model

Defining high-flow seasons using temporal streamflow patterns from a global model

Spatial and temporal variability of rainfall in the Nile Basin

Large‐scale atmospheric circulation and global sea surface temperature associations with Horn of Africa June–September rainfall

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