Existential threats to the iconic River Nile identified
University of Southern California researchers have identified a number of existential threats to the iconic Nile river delta
Large-scale heavy metal pollution, coastal erosion and seawater intrusion pose an existential threat to the Nile river delta and endanger 60 million people (about twice the population of Texas) in Egypt who depend on its resources for every facet of life, according to new research from the USC Viterbi School of Engineering.
Furthermore, the Nile river delta is a critical stopover for migrating birds across their journey along the East African flyway.
The impact of the pollution is especially pronounced in Egypt, the most populous and arid nation downstream of the Nile, which depends entirely on the river as its only source of water for drinking and crop irrigation.
The country currently faces one of the highest water budget deficits in Africa after decades of compensating for dwindling water supplies with intensive, large-scale wastewater reuse, the consequences of which have been understudied until now.
Study lead Essam Heggy, from the USC Viterbi Innovation Fund Arid Climates and Water Research Center, said: “You have roughly the combined populations of California and Florida living in a space the size of the state of New Jersey that is increasingly polluted by toxic heavy metals.
“Today, the civilisation that thrived in a scenic waterscape for over 7,000 years must face the reality of this irreversible large-scale environmental degradation.”
See also: Anthropogenic pollution worse than desert dust in Middle East
Recovering the Nile
For the study, researchers from the US and Egypt analysed grain size and pollution levels of eight heavy metals in samples of bottom sediment collected from two branches of the Nile river delta. Key findings included:
- Sediment at the bottom of the River Nile is highly polluted by heavy metals like cadmium, nickel, chromium, copper, lead and zinc;
- Contaminants primarily come from untreated agricultural drainage and municipal and industrial wastewater. Without proper treatment of recycled water, concentrations of heavy metals increase and are permanently embedded in the riverbed unlike organic pollutants which naturally degrade over time; and
- Heavy metal concentrations could be exacerbated by increased damming of the River Nile. Mega-dams built upstream disrupt the river’s natural flow and sediment flux and thus adversely affect its ability to flush contaminants out into the Mediterranean Sea, leaving toxins to build up in bottom sediment over time.
Much of the heavy metal contamination is irreversible, the researchers said, but science-based conservation measures suggested by the study can slow environmental degradation and hopefully recover the Nile river delta ecosystem.
Abotalib Z Abotalib, a postdoctoral researcher at USC Viterbi and co-author of the study, said: “The aggravating water stress and the rapid population growth in Egypt, reaching above 100 million, have put local authorities in a dilemma whether to provide sufficient fresh water for the thirsty agricultural sector to secure the food supply through reusing untreated agricultural drainage water or to preserve the health of the Nile River.
“The balance is challenging, and the consequences of both choices are measurable.”
Heggy added: “Our study underscores the need for more research on the environmental impacts of untreated water recycling and the change in river turbidity under increased upstream damming of the Nile.
“Continued research with more sampling campaigns in this area could inform future conversations and collaborations among nations of the Nile river basin, who have a shared interest toward maintaining a healthy Nile river system.”
The research is published in Earth’s Future.
Image: The River Nile is the longest river in the world and its delta is remarkable from outer space. © NASA. Public Domain.
