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Water Quality Mitigation Scenarios for Burullus Coastal Lake, Egypt

  • M. ElshemyEmail author
  • B. A. Zeidan
  • W. Assar
Conference paper
  • 79 Downloads
Part of the Springer Water book series (SPWA)

Abstract

Lake Burullus is the second largest coastal lagoon in Egypt, its ecosystem has been deteriorated, due to its central location inside the Nile Delta. The lake receives most of the drainage water of the Nile Delta region through eight agricultural drains. The drainage water which discharged into the lake is mostly nutrient-rich fresh water, polluted with agricultural fertilizer and heavy metals from industry. Lake Burullus is classified as hypereutrophic with bad to very bad environmental conditions. The main objective of this study is to investigate the feasibility of applying different water quality management scenarios to improve the lake ecosystem. A calibrated hydrodynamic and water quality model for the lake was developed using a two-dimensional, vertically averaged, finite difference hydrodynamic and ecological code, MIKE21. This developed model was calibrated with measured field data collected during the period (June 2010–July 2011). Three hydrodynamic parameters and five water quality parameters of the lake were chosen to present the study results. These parameters are: water levels, water temperature, salinity, dissolved oxygen, biochemical oxygen demand, nitrate, Ammonia and ortho-phosphate. Three enhancing water quality scenarios for the lake were investigated: an additional artificial outlet, treatment plants for drains discharge and constructing of radial channels in lake bed. The study results verified that, economically, treatment plants scenario for the two most polluted drains is highly recommended. Constructing of an additional outlet will increase the average lake salinity and is considered as the most effective scenario for enhancing the DO concentrations in the lake. A water quality management strategy is urgently required for the lake ecosystem.

Keywords

Lake burullus MIKE 21 Nile delta Ecology 

Abbreviations

AME

Absolute Mean Error

BOD

Biochemical Oxygen Demand

COD

Chemical Oxygen Demand

DO

Dissolved Oxygen

GIS

Geographical Information System

NH4

Ammonium

NO3

Nitrates

PO4

Phosphate

RMS

Root Mean Square Errors

Sc.n

Scenarios No. n

Sn

Station No. n

Notes

Acknowledgements

The authors extremely thank Prof. Dr. Ibrahim El-Shinnawy, the former Director of Coastal Research Institute (CORI), Egypt, and the Egyptian Environmental Affairs Agency (EEAA) for providing field records for Lake Burullus. Sincere thanks must go to the reviewers who participated in enhancing of the quality of this chapter.

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Copyright information

© Springer Nature Singapore Pte Ltd. 2020

Authors and Affiliations

  1. 1.Faculty of EngineeringTanta UniversityTantaEgypt
  2. 2.Faculty of EngineeringAl-Baha UniversityAl-BahaSaudi Arabia

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