Your search found 5 records
1 Abed, L.; Hassan, A. A.. 1995. Preliminary numerical tests of the effect of water management on salt intrusion in the coastal delta aquifer in Egypt. Paper, National Water Research Center (Egypt), Strategic Research Program. 12p. (Working paper series no.26-1)
Salt water intrusion ; Water management ; Aquifers ; River basins ; Groundwater development ; Artificial recharge ; Strategy planning / Egypt
(Location: IWMI-HQ Call no: P 4048 Record No: H017455)
2 Hassan, A. A.; Karim, N. N. 2001. Field water balance in wheat cultivation. Journal of Applied Irrigation Science, 36(2):203-211.
Water balance ; Evapotranspiration ; Wheat ; Soil moisture ; Soil water ; Percolation ; Irrigated farming / Bangladesh
(Location: IWMI-HQ Call no: PER Record No: H029679)
3 Rahman, W. A.; Adanan, C. R.; Hassan, A. A.. 2002. Species composition of adult Anopheles populations and their breeding habitats in Hulu Perak District, Peninsular Malaysia. The Southeast Asian Journal of Tropical Medicine and Public Health, 33(3):547-550.
Malaria ; Disease vectors ; Anopheles ; Waterborne diseases ; Public health / Malaysia / Hulu Perak District
(Location: IWMI-HQ Call no: PER Record No: H032245)
4 Hassan, A. A.; Birley, M. H.; Giroult, E.; Zghondi, R.; Khan, M. Z. A.; Bos, R. 2005. Environmental health impact assessment of development projects: A practical guide for the WHO Eastern Mediterranean Region. Cairo, Egypt: WHO Regional office for the Eastern Mediterranean. 131p.
Health ; Risks ; Epidemiology ; Impact assessment ; Environmental effects ; Water pollution ; Pollution control ; Air pollution ; Soil pollution ; Urbanization ; Irrigation programs / Eastern Mediterranean Region
(Location: IWMI-HQ Call no: 628 GG20 HAS Record No: H038960)
5 Sayed, E.; Riad, P.; Elbeih, S. F.; Hassan, A. A.; Hagras, M. 2020. Sustainable groundwater management in arid regions considering climate change impacts in Moghra Region, Egypt. Groundwater for Sustainable Development, 11:100385. [doi: https://doi.org/10.1016/j.gsd.2020.100385]
Groundwater management ; Sustainable use ; Climate change ; Solar energy ; Arid zones ; Pumping ; Aquifers ; Geographical information systems ; Sea level / Egypt / Moghra Region / Moghra Aquifer
(Location: IWMI HQ Call no: e-copy only Record No: H050093)
(3.67 MB)
Egypt is one of the most water-scarce countries of the Middle East and North Africa region and is highly vulnerable to climatic changes. In the Egyptian deserts, new land reclamation projects depend mainly on groundwater as the main source of water. Also, solar energy is the most promising renewable source of energy for pumping and transport of water. Moghra region is one of the well-known “1.5 Million Acres Reclamation Projects” areas in the Western Desert. In this paper, a groundwater model was constructed and used to investigate the sustainable groundwater management scenarios in Moghra region taking into consideration impacts of the expected climate changes. Using MODFLOW/GMS software, Moghra model was prepared and calibrated based on the region's topographic, climatic, geologic and hydrologeolgic conditions. The model was used to explore the impacts of climate changes; Sea Level Rise (SLR) by 1.0 m and temperature increase by 2°0C and 40°C on the management scenarios. In addition, the required power for water management after 5, 10, 50 and 100 years were determined. It was concluded that the best management scenario is to use 1000 wells to extract 1.2 Mm3/d of water for serving a total area of 85,714 acres (360 km2). This scenario satisfies the project criteria that permits a maximum drawdown less than 1 m/year. It was also concluded that SLR has mild effects on groundwater levels due to the vast aquifer dimensions. Additionally, the increase in evapotranspiration due to temperature increase will lead to a significant increase in the consumptive use. The power needed to extract water will continuously increase due to the expected increase in drawdown. The required area for Photovoltaic (PV) solar plant was determined and its value increased by 6% and 12% due to temperature increase of 2°C and 4°C, respectively.
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