Fact-checked by Grok 2 weeks ago

Blue Nile

The Blue Nile, known locally as the Abay in , is a principal of the River originating from in the . It flows approximately 1,500 kilometers northwest through rugged terrain in and , descending through dramatic gorges and contributing vital seasonal floods before merging with the at to form the main . The river delivers about 60 percent of the 's total annual discharge measured at , along with the majority of its , which historically enriched downstream floodplains for and . Central to the of northeastern , the Blue Nile's flow is driven by rains in its Ethiopian headwaters, peaking from to September and enabling hydropower development, as exemplified by Ethiopia's , the continent's largest, which has sparked international tensions over and riparian rights. Despite its critical role, the basin faces challenges from climate variability, , and upstream damming, which alter downstream flows and , underscoring the need for cooperative transboundary management among , , and .

Geography

Origin and Upper Course in Ethiopia

The Blue Nile originates at , located in the northwestern within the . , Ethiopia's largest lake, spans approximately 3,050 square kilometers at an elevation of 1,830 meters above . The lake measures about 84 kilometers in length and 66 kilometers in width, serving as the primary reservoir for the river's initial flow. Lake Tana receives inflows from over 40 rivers and streams originating in the surrounding highlands, with more than 95 percent of the water contributed by four major tributaries: the Gilgel Abbay (Little Abbay), Megech, Gumara, and Rib rivers. These rivers drain the plateau of the northwestern highlands, channeling and runoff from elevations exceeding 2,000 meters. The Gilgel Abbay, often regarded as the primary headstream, emerges from springs in the Sakala Mountains before feeding into the lake. Upon exiting near the town of , the Blue Nile, known locally as the Abay, flows northward for approximately 25 kilometers before plunging over the Tis Issat Falls, where it drops 50 meters into the Blue Nile Gorge. This , historically a significant barrier to , marks the transition from the lake's outlet to the river's incised upper course through rugged terrain. Beyond the falls, the river carves a deep gorge, descending rapidly across the Ethiopian Plateau via a series of cascades and narrow valleys, losing toward the Sudanese over a distance of roughly 800 kilometers within . The gorge's steep walls and meandering path reflect the erosive power of the river on the volcanic bedrock of the highlands.

Lower Course in Sudan and Confluence

Upon entering Sudan from Ethiopia near the border town of Roseires at approximately 11°50′N latitude, the Blue Nile flows northwestward across the relatively flat Gezira Plain, a semi-arid region characterized by low gradients and seasonal flooding prior to dam regulation. This segment spans roughly 600 kilometers to Khartoum, with the river widening in places and supporting alluvial soils conducive to agriculture. The course features two major dams: the Roseires Dam, a concrete buttress structure completed in 1966 near Ad Damazin, which impounds the river for generation (280 MW capacity), irrigation, and flood mitigation, creating Lake Roseires with a surface area of about 188 square kilometers at full supply. Downstream, approximately 260 kilometers, lies the Dam, an earthfill and finished in 1925 near town, primarily for diverting water into the Gezira Canal to irrigate over 800,000 hectares in the Al Jazirah scheme, though it also provides limited (15 MW). These structures have altered the natural flow, reducing peak discharges and downstream. Approaching Khartoum, the Blue Nile meanders through urbanizing areas before converging with the White Nile at Al-Mogran, a sharp-angled junction about 1 kilometer south of the city's confluence point, where the combined waters form the main River flowing northward. The Blue Nile, carrying heavier sediment loads from , often maintains visible turbidity differences with the clearer White Nile for several kilometers post-confluence, though monsoon-driven high flows can occasionally induce effects near the junction during peak seasons. This meeting point, at roughly 15°18′N 32°32′E, underscores the Blue Nile's hydrological dominance, supplying about 59% of the 's annual discharge despite its shorter length.

Hydrology

Flow Regime and Seasonal Variations

The Blue Nile's flow regime is predominantly , driven by seasonal rainfall in the rather than glacial or nival melt, resulting in stark contrasts between low and high discharge periods. flows, spanning November through May, are severely limited, accounting for approximately 4% of annual discharge and relying mainly on from aquifers and minor tributaries. This period sees minimal , with exceeding inflows, constraining river levels to sustain only basic ecological and human needs in downstream reaches. The onset of the main rainy season in June, fueled by convergence of moist air masses over the Ethiopian Plateau, initiates rapid hydrograph rises, with the bulk of annual precipitation—typically 1,000–1,800 mm in the upper basin—falling between June and September. Over 80% of the river's yearly discharge occurs from July to October, peaking in August or September as cumulative runoff from steep, erodible catchments amplifies volumes. Peak flows can reach several times the annual mean of around 1,600 cubic meters per second at the Sudanese border, transporting vast sediment loads while flooding riparian zones. Interannual variability modulates this cycle, with El Niño-Southern Oscillation events influencing rainfall onset and intensity, though long-term records show no significant trend in overall flow magnitude amid stable hydroclimatic patterns. Reservoir operations, such as those at Roseires and in , now mitigate some extremes by storing floodwaters for dry-season release, altering natural variability downstream.

Discharge Rates and Contributions to the Nile

The Blue Nile exhibits a mean annual discharge of approximately 1,540 m³/s near its outlet from the into , based on long-term gauged records from 1912 to 1997. This equates to roughly 48.5 km³ per year, with minor additions from Sudanese tributaries such as the Dinder River contributing an additional 3 km³ annually on average. Discharge is markedly seasonal due to the monsoon-driven rainfall in the , with over 80% of the annual flow concentrated in the flood period from July to October, when peak rates can surpass 9,000 m³/s. In contrast, dry-season flows from November to June average below 200 m³/s, occasionally dropping as low as 100 m³/s, reflecting minimal from and outflows. These variations are exacerbated by high rates and sediment loads during floods, which can temporarily reduce effective water yield through deposition. The Blue Nile accounts for about 60% of the total flow in the main Nile at Khartoum, where it converges with the White Nile, providing the dominant hydrological input to the combined system prior to the Atbara River's junction further north. This contribution underscores its critical role in sustaining downstream water availability, with the Ethiopian-sourced portion alone yielding around 50-54 km³ annually, far exceeding the steadier but lower-volume White Nile input of approximately 28%. Hydrological models confirm this disproportionate reliance, attributing 55-59% of the Nile's pre-dam natural flow at Aswan to Blue Nile origins when accounting for evaporation losses in swamps and reservoirs.

Ecology and Environment

Biodiversity and Ecosystems

The Blue Nile basin encompasses a range of ecosystems, from the montane highlands and afro-montane forests of Ethiopia's upper reaches to riverine floodplains and woodlands in , supporting transitional habitats that bridge highland endemism with lowland migratory corridors. These ecosystems include wetlands around , the source of the river, deep gorges such as the Blue Nile Gorge, and seasonal floodplains that foster riparian vegetation like gallery forests and swamps. The basin qualifies as a Biodiversity Area due to its role in conserving from multiple biomes, including taxa that utilize riverine corridors for dispersal. Aquatic biodiversity is particularly pronounced in the Ethiopian portion, where the river originates from and descends through the Tisisat Falls, creating distinct faunal zones. hosts an endemic cyprinid radiation of approximately 18 Labeobarbus species, many commercially fished and adapted to lacustrine conditions, representing a high level of driven by isolation in the . Below the falls, the riverine stretch supports a different assemblage dominated by migratory species such as Labeobarbus intermedius, which exhibits peak spawning from the fourth week of June to the second week of July, alongside other Nilo-Sudanic and East African elements contributing to over 200 freshwater fish species across Ethiopia's Blue Nile system. In the Sudanese Blue Nile, fish diversity includes at least 73 species, with common taxa like catfishes ( spp.) and tilapias inhabiting reservoirs and main channel habitats. Terrestrial and riparian biodiversity features Ethiopian highland endemics alongside widespread taxa, including reptiles such as crocodiles ( niloticus) and monitor lizards in fringes, and mammals like hippopotamuses in deeper pools. Avian communities thrive in wetlands and river heads, with surveys in the southern Gulf of and upper recording diverse waterbirds, passerines, and raptors during wet (June–October) and dry seasons, reflecting seasonal migrations tied to flood pulses. In Sudanese eastern localities, bird richness peaks in habitats with up to 35 observed across families like and Ardeidae, while mammals include 10 such as and ungulates adapted to savanna-woodland interfaces. An endemic in the mid-Abbay basin can reach pest levels, impacting local and underscoring insect diversity in riparian zones. Overall, the 's ecosystems sustain a subset of the 's thousands of plant and animal , with concentrated upstream due to topographic barriers like gorges and falls.

Environmental Impacts and Challenges

Soil erosion in the Upper Blue Nile Basin represents a primary environmental challenge, driven by , intensive , and steep in the . Annual soil loss rates average 39.73 tons per across the basin, with the Upper Blue Nile experiencing up to 57.98 tons per , contributing to that clogs reservoirs and reduces downstream . This erosion totals approximately 303 million tons of lost yearly from the highlands, exacerbating and diminishing agricultural productivity. Poor land management practices, including and cultivation on slopes without measures, intensify these rates, leading to formation and . Water quality degradation further compounds challenges, with industrial effluents, agricultural runoff, and untreated sewage introducing such as , , , , lead, and into the river system. In , assessments reveal elevated levels of pollutants like and total alkalinity exceeding limits for , particularly near urban discharge points. Organic contaminants and accumulation in sediments pose risks to aquatic life and human health, with sediments classified as moderately to highly polluted due to untreated . These inputs stem from expanding factories and activities, diluting natural dilution effects during low-flow periods. Climate variability and projected changes amplify hydrological instability, with models forecasting increased by 7-48% and rises of 21-97% in the Upper Blue Nile, heightening risks while dry-season reductions could strain ecosystems. Enhanced seasonal variability, including more intense rainy-season flows and diminished off-season , disrupts riparian habitats and exacerbates during extreme events. Such shifts, linked to broader flow standard deviation increases of about 50%, threaten integrity and adapted to historical regimes. Biodiversity loss accompanies these pressures, as land-use changes and degradation have converted forests to farmland, reducing native tree and shrub diversity in Blue Nile forests and fragmenting ecosystems. Local perceptions in Ethiopian sub-basins identify since 2008 as the dominant ecological issue, correlating with deterioration and proliferation. Over 26% of Ethiopian land, including Blue Nile areas, suffers degradation, impacting livelihoods and accelerating habitat loss for endemic and . Dams along the Blue Nile, such as those predating recent large-scale projects, trap sediments and alter flow dynamics, reducing downstream nutrient delivery and promoting channel incision or . Reservoir sedimentation shortens infrastructure lifespan and disrupts food webs by limiting essential for delta maintenance. These modifications, combined with over-extraction for , foster hypoxic zones and invasive vegetation, challenging efforts amid population-driven demands.

History

Early Exploration and Mapping

Ancient civilizations, including the , were aware of the Blue Nile's existence and its seasonal floods contributing to the 's inundation, though its Ethiopian origins remained obscure and uncharted in detail prior to the . Early attempts at mapping the system, such as those by in the 2nd century AD, depicted generalized southern sources but lacked precision on the Blue Nile's headwaters, relying on traveler reports rather than direct observation. The first documented European exploration of the Blue Nile's source occurred in the early 17th century when Spanish Jesuit missionary Pedro Páez reached the river's feeder springs approximately 60 kilometers south-southwest of at the foot of Mount Gish in 1618, confirming the lake as the primary reservoir for the river's upper course. Páez's findings, based on direct traversal and local knowledge, provided initial European insights into the but were not widely disseminated or mapped in until centuries later due to limited publication and political isolation of Ethiopia. In the , Scottish explorer undertook a dedicated expedition from 1768 to 1773, traveling through , , and to trace the Blue Nile. On November 4, 1770, Bruce reached the outlet of at the Tis Issat Falls, hiking approximately 70 miles into the surrounding mountains to observe the river's emergence from the lake, which he identified as the Nile's —a claim he asserted as the first by a European despite Páez's prior visit. Bruce's detailed accounts, published in 1790 as Travels to Discover the Source of the Nile, included rudimentary sketches and descriptions that advanced European mapping by delineating the river's course from northward through Ethiopia's gorges and into , though inaccuracies persisted due to reliance on visual estimation rather than instrumental surveying. Subsequent 19th-century efforts by British and other explorers refined these mappings through and barometric measurements, but Bruce's work marked a pivotal shift from speculative to empirical observation, influencing later cartographic representations that accurately bifurcated the into White and tributaries converging at .

Role in Regional Conflicts and Development

The Blue Nile's strategic location facilitated military campaigns during the Mahdist War (1881–1899), as Mahdist forces under Muhammad Ahmad seized control of riverine territories between the White and Blue Niles, enabling southward advances toward Ethiopia and sustaining garrisons along its banks. The river's confluence with the White Nile at Khartoum served as a critical defensive and logistical hub, where Mahdist leader Abdallahi ibn Muhammad established administrative control, though British-Egyptian reconquest in 1898 restored Anglo-Egyptian authority over these waterways. This conflict underscored the Blue Nile's role in intra-regional power struggles, with river control determining supply lines and territorial dominance in Sudan. In the colonial era, the British prioritized the Blue Nile for economic development in , constructing the Sennar Dam, completed in 1925, to regulate flows and irrigate the Gezira Plain, transforming arid lands into a major cotton-producing region that spanned approximately 880,000 hectares by the mid-20th century. This infrastructure, part of broader storage schemes, boosted agricultural output and export revenues, with Gezira cotton accounting for over 50% of Sudan's exports by 1950, though it also entrenched dependency on seasonal floods until regulated. Subsequent projects, such as the Roseires Dam initiated in 1956 under the Century Storage Scheme, further expanded hydropower capacity to 280 MW and additional irrigation, supporting post-independence agricultural intensification amid growing downstream demands from . Tensions arose from colonial-era treaties restricting upstream development, notably the 1902 Anglo-Ethiopian agreement, in which Emperor Menelik II pledged consultation with on any Blue Nile projects near to safeguard Egyptian , effectively limiting Ethiopian infrastructure until the mid-20th century. These pacts reflected Egypt's historical dominance over allocations, as formalized in the 1929 Anglo-Egyptian Treaty granting Egypt veto power over upstream works, which Sudan later challenged but which stifled Ethiopian harnessing of the river's 59% contribution to flow for local development. Such arrangements fueled latent conflicts, evident in Ethiopia's aborted 1970s dam proposals met with Egyptian opposition, highlighting the Blue Nile's centrality to riparian power imbalances. The river's basins also hosted internal Sudanese insurgencies with developmental grievances, as marginalized ethnic groups in Blue Nile State contested central government control over resources, with roots tracing to post-colonial neglect of local despite expansions that favored mechanized schemes over subsistence farming. By the , cumulative dam storage on the Blue Nile had mitigated floods but intensified debates over equitable benefits, setting precedents for later transboundary disputes.

Economic Utilization

Irrigation and Agricultural Dependence

The Blue Nile supplies approximately 60% of the Nile River's mean annual flow, making it a critical resource for irrigation-dependent in downstream and . This contribution is particularly vital during the July-to-September season, when Ethiopian highlands rainfall drives peak discharges that historically enabled flood-based farming and now support regulated canal systems. In , the represents the world's largest gravity-fed irrigation system under unified management, spanning the fertile plain between the Blue and White Niles south of . Water is diverted from the Blue Nile via the Sennar Dam, constructed between 1925 and 1927, which impounds a 930 million cubic meter and channels flow through main canals to irrigate tenant farms producing , , , and groundnuts. The scheme covers over 880,000 hectares under cultivation, supporting roughly 20% of Sudan's agricultural output and employing hundreds of thousands in a country where agriculture accounts for about 30% of GDP and 80% of the workforce. Dependence on Blue Nile inflows is acute, as schemes like Gezira, Rahad, and New Halfa rely on seasonal releases for perennial cropping, with disruptions risking , reduced yields, and food insecurity. Egypt's agricultural sector, which utilizes over 90% of its water allocation for across 3.5 million hectares of in the Nile Valley and , indirectly hinges on Blue Nile volumes to maintain the river's overall discharge. While the High buffers variability, Blue Nile silt and flow sustain and downstream reservoirs, enabling multi-cropping of , , and that feed 100 million people. In the Sudanese Blue Nile Basin alone, agricultural land constitutes 44.56% of the nation's total cultivable area, underscoring regional vulnerability to upstream flow alterations. Overall, withdraws about 80% of the river's , with Blue Nile dominance amplifying risks from variability, , and transboundary storage projects.

Hydropower and Infrastructure Projects

The Grand Ethiopian Renaissance Dam (GERD), located on the Blue Nile in Ethiopia's approximately 30 kilometers upstream from the Sudanese border, represents the largest project on the river, with an installed capacity of 5,150 megawatts upon its completion in September 2025. Construction began in 2011 at a cost of approximately $5 billion, funded primarily through domestic resources including government bonds and worker contributions, with the dam reaching full operational status after generating initial power from 2022 onward. The stands 476 feet high and spans 1.2 miles, creating a capable of producing an estimated 15,700 gigawatt-hours annually, effectively doubling Ethiopia's national electricity output and enabling exports to neighboring countries. As part of the project, ancillary infrastructure includes two bridges spanning the Blue Nile for site access, along with roads, worker housing, and an airstrip facilitating construction and operations. Downstream in , earlier hydropower facilities on the Blue Nile include the Roseires Dam, completed in 1966 and subsequently heightened to enhance capacity, which generates 280 megawatts primarily for electricity and regulation. The Sennar Dam, constructed in 1925 as the first major structure on the river for the Gezira irrigation scheme, supports 50 megawatts of installed later for supplemental power generation amid its primary role in diverting water to over 4.5 million hectares of farmland. These dams, with reservoirs totaling billions of cubic meters, manage seasonal flows but face challenges that reduce long-term efficiency without coordinated upstream operations. Additional Ethiopian projects, such as the Tis Abay I and II hydroelectric plants near Lake Tana's outlet, contribute smaller-scale output—totaling around 75 megawatts—by harnessing falls on the upper for early grid expansion since the 2000s. Infrastructure developments tied to include key bridges across the Blue Nile Gorge, such as the cable-stayed Abay River Bridge in , inaugurated in May 2024 with a 380-meter span to improve regional connectivity and trade along the river's course. Similarly, the Hadase Bridge, completed in 2008, spans 303 meters to link highways traversing the gorge, reducing transit times and supporting economic access to sites. These crossings, often engineered amid challenging terrain, facilitate maintenance and population growth around Blue Nile facilities but require ongoing investment to withstand floods and erosion.

Geopolitical Significance

Historical Water Treaties and Disputes

The Blue Nile's water allocation has been shaped by colonial-era agreements that prioritized downstream users, particularly . The 1929 Anglo-Egyptian Treaty, signed between and the representing its East African colonies including , granted the majority of Nile waters and veto rights over any upstream projects that might reduce flow to , without consulting or including , the primary source of Blue Nile waters contributing approximately 59% of the 's total discharge. This treaty effectively ignored 's riparian rights, as was independent and not a party to the negotiations. Building on this framework, the 1959 Nile Waters Agreement between and divided the estimated 84 billion cubic meters of annual Nile flow—after accounting for evaporation—allocating 55.5 billion cubic meters to and 18.5 billion to , presuming Ethiopia's contribution as a free gift with no allocation for upstream use or losses. , contributing the bulk of the Blue Nile's flow from , was entirely excluded from the agreement and has consistently rejected its applicability, arguing it violates principles of equitable utilization under international water law. These treaties fostered long-standing disputes, as upstream states viewed them as relics of colonial imposition that disregarded their developmental needs and over originating waters. In response to these imbalances, upstream Nile Basin countries pursued the 2010 Cooperative Framework Agreement (CFA), which emphasizes equitable and reasonable utilization, protection of ecosystems, and cooperation without veto powers, directly challenging the perpetual downstream priorities of prior pacts. Signed initially by , , , , and , the CFA has been ratified by eleven basin states as of 2024, with South Sudan's ratification triggering its pending procedural steps, though and have refused to join, citing threats to their established shares. Tensions escalated with Ethiopia's construction of the Grand Ethiopian Renaissance Dam (GERD) on the Blue Nile, begun in 2011, designed to generate 5,150 megawatts of with a reservoir capacity of 74 billion cubic meters. has invoked the 1929 and 1959 agreements to demand binding guarantees against flow reductions, fearing impacts on its and population dependent on the for 97% of freshwater, while Ethiopia asserts the project causes no significant harm and benefits all through regulated flow. A 2015 Declaration of Principles signed by , Ethiopia, and committed to cooperation and no significant harm, but negotiations on filling schedules and drought operations collapsed by 2020 when Ethiopia unilaterally began impoundment, leading to diplomatic stalemates and threats of escalation without a comprehensive superseding colonial legacies. Ethiopia maintains that , including the UN Watercourses Convention, supports its non-navigable use rights as the basin's origin state, rejecting downstream vetoes as outdated.

Grand Ethiopian Renaissance Dam and Ongoing Tensions

The (GERD), located on the Blue Nile River in Ethiopia's approximately 30 kilometers upstream from the border, is a standing 155 meters tall and 1,780 meters long, with a capacity of 74 billion cubic meters. Construction began in April 2011 following a $4.8 billion contract award, primarily funded by through domestic bonds and government revenues, aiming to generate 5,150 megawatts of hydroelectric power—enough to more than double the country's output and enable exports to neighboring states. The reservoir filling occurred in progressive phases amid unilateral decisions by : the initial fill of 4.4 billion cubic meters in July 2020 during seasonal high flows; subsequent phases in 2021 (adding 18.4 billion cubic meters), 2022, 2023, and the fifth and final phase completed in October , reaching full capacity at 640 meters elevation with 64 billion cubic meters stored. Power generation commenced with the first 375 MW turbine operational on February 20, 2022, followed by a second turbine in August 2022, progressive additions through , and full operational capacity of 5,150 MW achieved by September 9, 2025, upon inauguration, producing an estimated 15.76 terawatt-hours annually. maintains the dam's operation will not significantly reduce downstream flows long-term, citing minimal evaporation losses (around 3-4% of annual Blue Nile inflow of approximately 84 billion cubic meters) and the design's intent to release after generation, potentially aiding flow regulation during droughts or floods. Tensions escalated primarily with , which depends on the for over 90% of its freshwater needs, supporting that employs one-third of its and irrigates 96% of cultivated land, fearing disruptions during filling phases or dry periods that could exacerbate shortages. Sudanese concerns focus on irregular flows affecting its own dams like Roseires and , though the GERD could mitigate flooding in wet seasons; has oscillated between calls for binding agreements and conditional support. and Sudan invoke colonial-era treaties (e.g., 1959 Anglo-Egyptian agreement allocating 55.5 billion cubic meters annually to ) as customary rights, while rejects these as inequitable, having contributed 85% of waters without allocation, and proceeded without consensus under the 2010 Cooperative Framework Agreement, which has not fully ratified. Trilateral negotiations, mediated intermittently by the , , and others since 2011, repeatedly stalled over Ethiopia's refusal of legally binding drought mitigation clauses or extended filling timelines, with Egypt demanding veto-like safeguards and Ethiopia prioritizing sovereignty and development needs for its 120 million population, 60% of whom lack electricity access. No comprehensive agreement emerged by 2025, despite AU-brokered talks in 2023-2024; Ethiopia's October 2024 full filling declaration and September 2025 inauguration proceeded unilaterally, prompting Egyptian protests and warnings of existential threats, as articulated by on October 18, 2025, framing the as a "matter of existence." Independent hydrological models indicate potential short-term flow reductions of up to 25% in worst-case scenarios without coordination, but long-term impacts remain limited if operated for power rather than , underscoring risks from non-cooperation rather than inherent effects. Ongoing disputes heighten regional security risks, with Egypt exploring military options and alliances in the , though mutual deterrence and economic interdependence have thus far prevented escalation.

References

  1. [1]
    [PDF] People and Place - University of Texas at Austin
    Lake Tana, with its many ancient monasteries, is the source of the Blue Nile. From there the Blue Nile. (or Abbay, as it is called in Ethiopia) flows in an arc ...
  2. [2]
    Egypt and the Hydro-Politics of the Blue Nile River - Project MUSE
    While the White Nile is 5,584 km long, the Blue Nile covers a distance of 1,529 km from its source in Lake Tana to Khartoum, where both join and then flow ...Missing: origin | Show results with:origin
  3. [3]
    Advances in water resources research in the Upper Blue Nile basin ...
    Several hydrological models have been applied in the Upper Blue Nile basin to understand hydrological processes and estimate catchment water balance. The ...
  4. [4]
    Comparison and hydrological evaluation of different precipitation ...
    Mar 30, 2025 · As a critical source of water, the Blue Nile contributes about 60% of the Nile's total flow (Conway, 2005). The drainage area of the Blue Nile ...<|control11|><|separator|>
  5. [5]
    Understanding the hydrologic sources and sinks in the Nile Basin ...
    Oct 7, 2014 · Dominant water supply and sinks in the Nile Basin have been identified Four countries show a positive, and three countries show a negative ...
  6. [6]
    (PDF) Lake Tana: Source of the Blue Nile - ResearchGate
    At 1,830 m altitude, Lake Tana is situated on the basaltic Plateau of the north-western highlands of Ethiopia covering an area of ca 3,050 km2.Missing: origin facts elevation
  7. [7]
    Earth from Space - Image Information - NASA
    The lake is 47 miles (76 kilometers) long, 44 miles (71 kilometers) wide, and sits at an elevation of 6000 feet (1830 meters) above sea level. One of the many ...Missing: upper course
  8. [8]
    Lake Tana Project Area - NABU beyond borders
    Approximately 84 kilometres in length and 66 kilometres wide, Lake Tana is Ethiopia's largest lake and, at an elevation of 1840 meters above sea level, it is ...Missing: upper | Show results with:upper
  9. [9]
    Blue Nile | Initiatives pour l'Avenir des Grands Fleuves
    Total length: 1,600km (Blue Nile)/ 6,700 km (whole river); Watershed: 325,000 km² (Blue Nile)/ 3,254,555 km² (total watershed); States crossed: Ethiopia ...
  10. [10]
    The Climate and Hydrology of the Upper Blue Nile River
    Aug 9, 2025 · This paper provides a review of the nature and variability of the climate and hydrology in the source region of the Blue Nile-the central Ethiopian Highlands.
  11. [11]
    Between the Dam and the Sea - InfoNile
    Dec 17, 2023 · The Sennar dam, built on the Blue Nile 260 kilometers downstream of Roseires, has a hydropower capacity of 15 megawatts and is a vital ...
  12. [12]
    Sudan - Roseires - International Hydropower Association
    Roseires Dam, a concrete buttress dam located in the Blue Nile, was commissioned in 1966 to supply irrigation and domestic water, and generate power.
  13. [13]
    Water Infrastructure in Sudan
    Sennar on the Blue Nile. Built in 1925 (capacity 0.07BCM); · Jebel Awlia on the White Nile. Built in 1937 (capacity 3.0BCM); · Khashm al-Girba on the Atbara.
  14. [14]
    Two Niles Meet - NASA Earth Observatory
    May 18, 2013 · The Blue Nile is fed by monsoon rains, and when rains are abundant, the Blue Nile can actually flow backward near its confluence with the White ...
  15. [15]
    Effects of climate change on water resources in the upper Blue Nile ...
    Sep 13, 2018 · Climate change scenario modelling suggested that the precipitation will increase from 7% to 48% and that streamflow from the BNB could increase ...Missing: monsoon | Show results with:monsoon
  16. [16]
    Forest Cover and Stream Flow in a Headwater of the Blue Nile
    The watershed declined from 16% forest cover in 1957 to 1% by 1986. The hydrological record did not reveal changes in the flow regime between 1960 and 2002 ...Missing: variations | Show results with:variations
  17. [17]
    Temporal variability of hydroclimatic extremes in the Blue Nile basin
    Mar 10, 2012 · The analysis showed that high and low river flows and rainfall depths do not vary in time in a fully random way but show a particular variation ...
  18. [18]
    [PDF] Twentieth and Twenty-First Century Water Storage Changes in the ...
    Mar 4, 2021 · The Blue Nile River originates at Lake Tana in the. Ethiopian highlands. It generates about 57% (50.6 BCM/yr.) of the total runoff to the Nile.
  19. [19]
    Impact of Climate Change on Hydrological Extremes (Floods and ...
    Jul 5, 2025 · The flow of the Blue Nile Basin is highly sensitive to even minor variations in rainfall, making it particularly vulnerable to climate change.Missing: regime | Show results with:regime
  20. [20]
    [PDF] The Hydrology of the Nile by JV Sutcliffe & YP Parks. IAHS Special ...
    Conway (1997) has shown that it is possible to reproduce the 1951-1987 Blue Nile flow series near the Sudan border from distributed rainfall and potential ...
  21. [21]
    The Climate and Hydrology of the Upper Blue Nile River - jstor
    nificant waterfall, at Tis Isat, roughly 25 kilometres from Lake Tana where the river drops 50 metres into the Blue Nile gorge. Much of the highland plateau ...Missing: Issat | Show results with:Issat
  22. [22]
    Investigating hydro-climates of the Upper Blue Nile River Basin
    This paper will summarize what is known and frame the problem, then test various ways to quantify the key hydrological components of the Upper Blue Nile Basin ...Missing: reliable | Show results with:reliable
  23. [23]
    [PDF] Modeling the Nile: A Comprehensive Water Budget and Flow ...
    Dec 21, 2024 · The Blue Nile represents the largest tributary to the Main Nile providing an average annual flow of about 50 Billion Cubic Meters (BCM)) which ...
  24. [24]
    Understanding and managing new risks on the Nile with the Grand ...
    Oct 16, 2020 · The Blue Nile contributes ~55% of this flow, with the remaining 32% and 13% from the White Nile and Atbara, respectively. Fig. 1. Map of the ...
  25. [25]
    Mid-Abbay (Blue Nile) river basin (6250) Ethiopia, Africa
    The Abbay river system is likely to be important for Sudan–Guinea Savanna biome species and others from the lowlands, as is the case with the Jemma and Jara ...
  26. [26]
    [PDF] The Environmental Resources of the Nile Basin
    The Nile Basin has many unique aquatic and terrestrial ecosystems, and is home to thousands of species of plants and animals, many of them.
  27. [27]
    [PDF] Some aspects of the biology of dominant fishes in blue Nile River ...
    Jul 8, 2015 · the endemic species of Blue Nile basin occur exclusively in Lake Tana. The Blue Nile descends from Lake Tana to Tisisat Falls (ca. 40 m high) ...
  28. [28]
    Fish diversity in the Blue Nile system within the limits of Ethiopia
    The highest endemicity in Abay Basin can be explained mainly by the endemic flock of Labeobarbus spp. constituting 18 commercially important species of Lake ...
  29. [29]
    abundance and species composition of the fishes in blue nile river ...
    Aug 6, 2025 · Labeobarbus intermedius was the most abundant species followed by L. brevicephalus. The peak spawning season of L. intermedius was from fourth ...
  30. [30]
    [PDF] Fish diversity in the Nile system and ephemeral water bodies in Sudan
    Jun 7, 2024 · The relative abundance showed that there are at least 111 species in White Nile, 73 in Blue Nile, 36 in Dinder River, 38 in Atbara River and 63 ...
  31. [31]
    Avian species diversity in the southern Gulf of Lake Tana and head ...
    Avian study in the southern Gulf of Lake Tana and head of the Blue Nile River, Ethiopia was conducted from June 2016 to April 2017 during the wet and dry ...Missing: biodiversity | Show results with:biodiversity
  32. [32]
    Birds/mammals Biodiversity in Shergelneel Locality (Eastern Blue ...
    Mar 11, 2024 · The results showed that there were 35 bird's, and, 10 mammal's species in the three habitats. Maximum species richness of birds were recorded from Wadi habitat.
  33. [33]
    Soil erosion assessment in the Blue Nile Basin driven by a novel ...
    Nov 1, 2021 · The results showed that the mean soil loss rate is 39.73, 57.98, and 6.40 t ha−1 yr−1 for the entire Blue Nile, Upper Blue Nile, and Lower Blue ...
  34. [34]
    Impacts of climate change on soil erosion and sediment yield in the ...
    Oct 2, 2025 · The Ethiopian highlands, especially the Upper Blue Nile Basin, are severely affected, losing nearly 303 million tons of soil annually [29], ...
  35. [35]
    [PDF] Characterizing of erosion, sedimentation and evaluation of impact of ...
    The upper Blue Nile is heavily affected by watershed management problems, caused by overpopulation, poor cultivation and land use practices, deforestation and ...
  36. [36]
    (PDF) Assessment of Water Quality of Blue Nile River in Sudan
    Dec 7, 2018 · The objectives of this study were to quantify the fresh water quality of Blue Nile River before processing, identify the pollutants, and to ...
  37. [37]
    Effects of Bahir Dar Textile Factory Effluents on the Water Quality of ...
    The mean values of dissolved oxygen, BOD5, and total alkalinity were above maximum permissible limits set by WHO for drinking water at head of Blue Nile River.
  38. [38]
    Irreversible and Large‐Scale Heavy Metal Pollution Arising From ...
    Mar 7, 2023 · Nile River sediments are moderately to highly polluted by Ni, Cd, Cr, Cu, Pb, and Zn Untreated agricultural drainage and municipal and ...<|separator|>
  39. [39]
    A review of the current status of the water quality in the Nile water ...
    Mar 18, 2024 · The Nile water basin has been contaminated by numerous pollutants such as toxic heavy metals and organic contaminants, therefore pushing the resident water ...
  40. [40]
    Effects of climate change on water resources in the upper Blue Nile ...
    Climate change scenario modelling suggested that the precipitation will increase from 7% to 48% and that streamflow from the BNB could increase by 21% to 97%.
  41. [41]
    Climate change and its impact on streamflow in the upper Blue Nile ...
    Apr 5, 2024 · Rainy season (June to September) precipitation becomes enhanced, while it becomes reduced during other seasons, hence mean annual decreased ...
  42. [42]
    Climate Change: The Nile River - Middle East Policy Council
    Climate change is predicted to increase the standard deviation of the Nile's flow by approximately 50 percent, indicating a doubled likelihood of both flooding ...
  43. [43]
    Deterioration of blue Nile forests and its ecological effects in the ...
    Feb 12, 2020 · The decrease in the biodiversity of trees and shrubs ... Forests in the region suffer from decimation and environmental degradation.
  44. [44]
    Local Perception on Effect of Land Degradation in the Blue Nile ...
    Oct 26, 2022 · The finding showed that all local farmers perceived that land degradation was the main local ecological problem since 2008 in the form of soil ...
  45. [45]
    Land Cover Change in the Blue Nile River Headwaters - MDPI
    According to a global land degradation assessment, more than 26% of Ethiopian land has been degraded, and 30% of the population's livelihood has been affected ...
  46. [46]
    Surface water and geomorphological changes of the Blue Nile ...
    Apr 25, 2024 · The accumulation of sediment in reservoirs created by dams may have several environmental effects, including impacts on aquatic ecosystems, ...<|separator|>
  47. [47]
    The impacts of land-use and land-cover change on wetland ...
    Jun 8, 2021 · Additionally, creating green infrastructure in the urban and peri-urban areas, restoration of degraded wetlands with native plants and promotion ...
  48. [48]
    Blue Nile River | Map, Start, Ethiopia, & Length | Britannica
    Sep 9, 2025 · Its length is about 907 miles (1,460 km). By far the greater part of the Blue Nile's waters come from such tributaries as the Dinder and Rahad ...
  49. [49]
    Mapping the Source Region of the Abbay/Blue Nile
    May 22, 2024 · The first known attempt to locate the source of the Nile River through a map was made by the classical Egyptian geographer Claudius Ptolemy in ...
  50. [50]
    [PDF] The Blue Nile
    The name of the first was Pedro Saez, a Spaniard who discovered two natural springs sixty kilometres south-southwest of Lake Tana at the foot of Mount Gish on ...
  51. [51]
    James Bruce Explores the Blue Nile to Its Source and Rekindles ...
    James Bruce (1730-1794) of Scotland declared that he was the first European to have discovered the primary source of the Nile.
  52. [52]
    Travels to Discover the Source of the nile, Volume III., by James Bruce.
    Travels to Discover the Source of the Nile, in the years 1768, 1769, 1770, 1771, 1772, and 1773. In five volumes.
  53. [53]
    Evolution of the Map of Sources of the Nile
    The first known “expedition” up the Nile was undertaken by two centurions sent by the Roman emperor Nero in the first century A.D. They failed, however, to get ...
  54. [54]
    [PDF] Sudan, Imperialism, and the Mahdi's Holy War - Teach Democracy
    Mar 14, 2014 · Ali established Sudan's colonial capital at Khartoum, where the White and Blue Nile rivers join to form the main Nile River, which flows north ...
  55. [55]
    Mahdist | Sudanese, Islamic, Revolutionaries - Britannica
    On September 23, 1896, the Mahdists were routed so completely at Dongola that the victory returned a sizable portion of northern Sudan to Egyptian control.
  56. [56]
    Battle of Omdurman | Definition, Significance, & Winston Churchill
    In February 1898 a Mahdist army of more than 12,000 men, under the command of Emir Mahmud Ahmad, moved north along the right bank of the Nile before striking ...
  57. [57]
    The imperialist past that started dam politics between Egypt, Sudan ...
    Mar 21, 2021 · As part of the Century Storage Scheme, in 1956 Sudan went ahead with plans to construct the Roseires Dam on the Blue Nile and expand the ...
  58. [58]
    Who Owns the Nile? Egypt, Sudan, and Ethiopia's History-Changing ...
    Mar 15, 2013 · In 1902 the British secured from the Ethiopian Emperor Menelik II an agreement to consult with them on any Blue Nile water projects, especially ...
  59. [59]
    Historical Roots of the Blue Nile Conflict between Egypt ... - ORSAM
    In the Britain-Ethiopia treaty dated May 15, 1902, Ethiopia agreed on not to build any constructions that might obstruct the river's waters on Lake Tana, the ...
  60. [60]
    Nile River Conflicts - The Organization for World Peace
    Disputes between Ethiopia, Egypt, and Sudan over Nile River water rights culminated into outright tensions in 1978 following Ethiopia's proposal of dam ...
  61. [61]
    [PDF] Blue Nile, its conflict dynamics, and the potential implications for the ...
    Mar 24, 2024 · Of particular relevance is Blue Nile's recent history of conflict within the Sudan People's Liberation Movement–North (SPLM-N).
  62. [62]
    The implications of further reservoir development on the Blue Nile in ...
    The implications of further reservoir development on the Blue Nile in Ethiopia: trade-offs between hydropower, irrigation and transboundary water security.
  63. [63]
    Water-Energy-Food Nexus Sustainability in the Upper Blue Nile ...
    Jan 29, 2019 · The Blue Nile is a major tributary of the Nile River and contributes about 60% of the total annual flow. This paper presents a framework for ...
  64. [64]
    The Nile River Basin: Lifeblood of a Continent
    Jun 23, 2025 · The Blue Nile, which begins at Lake Tana in Ethiopia, contributes up to 85% of the Nile's total flow during the rainy season (Swain, 2011).Missing: rates | Show results with:rates
  65. [65]
    Reforming Sudan's Gezira scheme - ScienceDirect.com
    Nov 1, 2020 · ... Scheme is one of the world's largest, probably the largest, irrigation scheme under one management. It is located on the Blue Nile, where the ...
  66. [66]
    Sudan - Sennar - International Hydropower Association
    The main purpose of the dam was to store and divert water for irrigation in the adjacent Gezira scheme, and for securing drinking water supply during the dry ...
  67. [67]
    Sudan - Gezira Rehabilitation Project (Vol. 1 of 2) : Annexes 1-4
    The Gezira scheme is an irrigated project lying between the White and Blue Niles. The scheme slopes gently downwards from the south to the north and west.
  68. [68]
    The Performance of Irrigation Schemes in Sudan Affected by ... - MDPI
    The Gezira, Rahad, and El-Gunied irrigation schemes depend mainly on the Blue Nile as their primary water source. However, the construction of the Grand ...
  69. [69]
    [PDF] WATER, AGRICULTURE, G OVERNANCE AND LIVELIHOODS
    Egypt and. Sudan are almost completely dependent on Nile water for irrigated agriculture. Sudan's arable land is estimated to be 105 million ha, with about ...
  70. [70]
    Data Analysis: How Will the Grand Ethiopian Renaissance Dam ...
    Nov 6, 2022 · The largest land areas to be cultivated for agriculture are provided by the Blue Nile Basin, which constitutes 44.56 % of the total land area to ...
  71. [71]
    [PDF] Agriculture, Food Security, and Livelihoods in the Nile Basin
    Agriculture is vital in the Nile Basin, contributing to GDP, employment, and food security. It is the largest water consumer, with 15 main farming systems.
  72. [72]
    Grand Ethiopian Renaissance Dam: Ethiopia's Dream Come True
    Sep 10, 2025 · With its 5,150 MW of installed capacity, GERD will double the country's energy production. To build the mega project, the course of the Blue ...Missing: details | Show results with:details
  73. [73]
    The Grand Ethiopian Renaissance Dam - The Reporter Ethiopia
    Sep 6, 2025 · GERD is nothing short of a game-changer. With a generating capacity exceeding 5.15-gigawatt, it will double Ethiopia's electricity output— ...
  74. [74]
    Ethiopia Inaugurates $5B Renaissance Dam, Africa's Largest ...
    Sep 9, 2025 · Webuild completes 14-year effort on the Blue Nile, delivering 5,150-MW capacity project that reshapes Ethiopia's grid and heightens regional ...
  75. [75]
    Ethiopia inaugurates Africa's biggest dam amid regional tensions
    Sep 9, 2025 · The 476-foot high, 1.2 mile-long dam will more than double Ethiopia's electricity capacity to 5,000 megawatts. Almost half of Ethiopia's 130 ...
  76. [76]
    Webuild: Grand Ethopian Renaissance Dam (GERD) inaugurated ...
    Sep 9, 2025 · With an installed production capacity of more than 5,000 MW and an expected annual output of 15,700 GWh, the GERD can generate energy equivalent ...
  77. [77]
    Grand Ethiopian Renaissance Dam Project (GERD) | Webuild Group
    The Grand Ethiopian Renaissance Dam is the largest hydropower project in Africa and will enable Ethiopia to become Africa's leading producer of sustainable, ...
  78. [78]
    Work begins to heighten Sudan's 280-MW Roseires Dam
    Aug 29, 2008 · Chinese companies have begun construction to increase the height of the 280-MW Roseires Dam on Sudan's Blue Nile to increase irrigation and ...Missing: capacity | Show results with:capacity
  79. [79]
    Value of Reservoir Operation Coordinating in Hydropower ...
    Oct 6, 2021 · These dams also generate electricity with 280 MW and 50 MW power at Roseires and Sennar dams, respectively [1].<|separator|>
  80. [80]
    TIS ABAY II HYDROELECTRIC PROJECT
    The commissioning of Tis Abay II Hydroelectric Project will boost the current installed hydropower capacity of the country from 375 MW to 450 MW (20% increase ...
  81. [81]
    Ethiopia inagurates a new modern Bridge over Blue Nile ( Abay) River
    May 27, 2024 · The bridge is located in the beautiful city of Bahir Dar, in north-east Ethiopia, over the famous Blue Nile (Abay) River at the very mouth of the biggest lake ...
  82. [82]
    Abay river Bridge
    The Abay River Bridge is a cable-stayed, extra-dosed bridge in Bahirdar, Ethiopia, 380 meters long, with a 43 meter width, and is part of the Great Trans ...Missing: infrastructure | Show results with:infrastructure
  83. [83]
    Hadase Bridge | PS Construction Co.,Ltd.
    The Hadase Bridge, completed in 2008, is 303m long with 3 spans, connecting the northwest highway through the Blue Nile River. It has a width of 9m.Missing: infrastructure | Show results with:infrastructure
  84. [84]
    Building bridges between Madison and Ethiopia
    Nov 26, 2018 · Building bridges between Madison and Ethiopia ... To cross the Blue Nile River in Bahir Dar, Ethiopia, there's only one option, short of braving ...
  85. [85]
    The limits of the new “Nile Agreement” - Brookings Institution
    Apr 28, 2015 · In 1929, an agreement was concluded between Egypt and Great Britain regarding the utilization of the waters of the Nile River—Britain was ...
  86. [86]
    Agreements that favour Egypt's rights to Nile waters are an ...
    Nov 4, 2018 · To this day Egypt argues that the 1929 Anglo-Egyptian Treaty and its modified version, the 1959 Agreement, are still valid. The 1959 ...
  87. [87]
    Colonial-era treaties are to blame for the unresolved dispute over ...
    Mar 25, 2020 · The obligation imposed in the 1902 Anglo- Ethiopian Treaty does not prohibit Ethiopia from using the Nile waters, even without the consent of ...
  88. [88]
    The Nile River "Conflict" | EARTH 111: Water: Science and Society
    A later treaty, the so-called 1959 Nile Waters Agreement between Egypt and Sudan, allocated 55.5 bcm/y to Egypt and 18.5 bcm/y to Sudan—the total allocation ...
  89. [89]
    The 1959 Agreement “for the full utilization of the Nile waters”
    Feb 15, 2022 · Ethiopia and all the other Nile basin countries are not party to the 1959 agreement and as such, they are not legally bound by the treaty.
  90. [90]
    The long shadow of the 1959 Nile Waters Agreement - IWA Publishing
    Aug 22, 2024 · HIGHLIGHTS. The 1959 Nile Waters Agreement created a strong disincentive for Sudan to participate in any new basin-wide water-sharing plan.
  91. [91]
    The Blue Nile dam controversy in the eyes of international law: Part 1
    Jun 18, 2013 · This was reinforced by the Nile Water Treaty 1959 signed between Egypt and Sudan for the “full utilisation of the Nile waters”,4 and the use of ...
  92. [92]
    Cooperative Framework Agreement - Nile Basin Initiative
    The text of the Cooperative Framework Agreement (CFA) outlines principles, rights and obligations for cooperative management and development of the Nile Basin ...
  93. [93]
    Entry into Force of the Nile Basin Cooperative Framework Agreement
    Aug 2, 2024 · On July 8, 2024, South Sudan announced that its Transitional National Legislative Assembly (TNLA) unanimously ratified the Nile Basin Cooperative Framework ...
  94. [94]
    [PDF] The Nile Basin Cooperative Framework Agreement
    The Nile Basin Cooperative Framework Agreement, opened in 2010, aims to challenge Egypt's monopoly over the Nile waters and assert rights of upper riparian ...
  95. [95]
    The controversy over the Grand Ethiopian Renaissance Dam
    Aug 5, 2020 · The tensions among Egypt, Sudan, and Ethiopia over the Grand Ethiopian Renaissance Dam (GERD) on the Blue Nile have escalated.Missing: excluding | Show results with:excluding
  96. [96]
    The politics of the Grand Ethiopian Renaissance Dam
    Feb 2, 2024 · Ethiopia has long distrusted Egyptian hegemony over the Nile which was established through colonial treaties designed to monopolise a lion's ...
  97. [97]
    Meeting on the Grand Ethiopian Renaissance Dam and Regional ...
    Jul 7, 2021 · On 23 March 2015, the three countries signed a Declaration of Principles on the GERD in Khartoum. The agreement was built around ten principles, ...Missing: treaties | Show results with:treaties
  98. [98]
    https://jtl.columbia.edu/volume-59/sink-or-swim-alternatives-for-unlocking-the-grand-ethiopian-renaissance-dam-dispute
  99. [99]
    Grand Ethiopian Renaissance Dam, Ethiopia | EROS
    Under construction since 2011, the Grand Ethiopian Renaissance Dam (GERD) is 1.1 miles long, 509 feet tall, and spans the Blue Nile River in Ethiopia.
  100. [100]
    The Grand Ethiopian Renaissance Dam: A Timeline
    Jun 17, 2020 · 2 April 2011. Ethiopia announces construction of the Grand Ethiopian Renaissance Dam (GERD) after signing a $4.8 billion construction contract ...
  101. [101]
    The Grand Ethiopian Renaissance Dam (GERD) - Grey Dynamics
    Initiated in April 2011, this colossal hydroelectric project will be Africa's largest dam. The estimated cost of constructing the dam is around $4 billion. And, ...
  102. [102]
    Ethiopia opens Africa's largest hydroelectric dam to Egyptian protest
    Sep 9, 2025 · The dam's output has gradually increased since the first turbine was turned on in 2022, and it reached its maximum 5,150 MW of power on Tuesday.
  103. [103]
    TIMELINE – How Ethiopia's Grand Renaissance Dam project unfolded
    Sep 9, 2025 · The idea of a dam on the Blue Nile dates back to pre-1964 studies by US engineers, but regional politics have long shaped the river's governance ...
  104. [104]
    Operation of the Grand Ethiopian Renaissance Dam: Potential Risks ...
    The results showed that GERD operation would cause an average 3.2% reduction in the Blue Nile flow to downstream countries due to evaporation losses from the ...
  105. [105]
    Ethiopia outfoxes Egypt over Nile waters with its mighty dam - BBC
    Sep 6, 2025 · It fears that dam could sharply reduce the flow of water to the country, causing water shortages. "About 93% of Egypt is desert, with almost no ...Missing: impact | Show results with:impact<|control11|><|separator|>
  106. [106]
    Full article: Trouble in the Nile Basin: Ethiopia, Egypt, and Sudan ...
    On April 7, 2021, Egyptian President Abdel Fattah al-Sisi warned of the risk of conflict over the dam after talks ended without progress. Gleick (Citation2018) ...
  107. [107]
    With Ethiopia's GERD Active, Tensions Mount Along the Nile
    Sep 25, 2025 · For Egypt and Sudan, who are downstream from the dam, the ongoing dispute with Ethiopia over water is perceived as an existential crisis that ...
  108. [108]
    As the Renaissance Dam Comes Online, the U.S. Mediation Role ...
    Sep 17, 2025 · Ethiopia, Egypt, and Sudan were unable to agree on crucial water-sharing rights in the fraught years leading up to the GERD's inauguration, ...
  109. [109]
    https://www.e-ir.info/2025/10/19/egypts-choices-on-the-grand-ethiopian-renaissance-dam/
  110. [110]
    Egypt PM: Nile River 'a matter of existence' amid rising tensions with ...
    Oct 18, 2025 · The GERD has been at the centre of a protracted dispute between Ethiopia, Egypt, and Sudan for over a decade. While Ethiopia views the dam as ...
  111. [111]
    Should Egypt be afraid of the Grand Ethiopian Renaissance Dam ...
    Dec 18, 2024 · These results show that it is possible to operate the GERD to exacerbate water shortages downstream in Egypt by withholding water during a multi ...INTRODUCTION · METHODS · RESULTS · DISCUSSION
  112. [112]
    "The GERD and Egypt's Water Security" by Farah Khayry
    The GERD could curtail Nile water flow to Egypt by 25%, jeopardizing water security and agriculture, which is a major food and employment source.
  113. [113]
    Egypt's Expanding Role in the Horn of Africa | Clingendael
    Oct 10, 2025 · These developments come at a time when Egypt is locked in a long-standing water dispute with Ethiopia over the Grand Ethiopian Renaissance Dam, ...<|separator|>
  114. [114]
    'Water Wars': strategic implications of the grand Ethiopian ...
    Sep 20, 2023 · Despite the challenges posed by factors such as climate change, population growth, and large-scale projects like the Grand Ethiopian ...