Potential impact of drought on Mikkes River flow (Morocco)
محورهای موضوعی :
Environmental Geology
Kaltoum Belhassan
1
,
Ashok Vaseashta
2
,
Mohammed Abdelbaset Hessane
3
,
Hafizullah Rasouli
4
,
Mohammed KA Kaabar
5
,
Emad Kamil Hussein
6
,
Muhammad Adnan
7
1 - Independent researcher in Water Environment, Dewsbury WF13 4QP, West Yorkshire, UK
2 - International Clean Water Institute, Manassas, VA USA |Riga Technical University, Institute of Biomedical Engineering and Nanotechnologies, Riga, Latvia
3 - Sidi Mohamed Ben Abdellah University, Immouzer Road, BP: 2626, Fez 30000, Morocco
4 - Department of Geology, Geoscience Faculty, Kabul University, Jamal Mina 1006, Kabul, Afghanistan
5 - Department of Mathematics and Statistics, Washington State University, Pullman 99163, WA, USA
6 - Mussaib Technical College, Al Furat Al Awsat Technical University, Mussaib P.O. Box 51006, Mussaib, Babil, Iraq
7 - Department of Agronomy, College of Agriculture, University of Sargodha, Pakistan
تاریخ دریافت : 1400/08/13
تاریخ پذیرش : 1401/04/03
تاریخ انتشار : 1401/10/11
کلید واژه:
Morocco,
drought,
temperature,
piezometric level,
rainfall,
Flow,
Mikkes River,
چکیده مقاله :
Mikkes River Basin is located in the north-center of the Kingdom of Morocco (North-West of Africa). It comprises of three different zones which represent diversified geologies and which shelter a phreatic and confined aquifer in Saïs plain and a shallow aquifer in El Hajeb Ifrane Tabular. This research aims to highlight the potential impact of drought on Mikkes River flow through climate indexes including rainfall, temperature and evapotranspiration during the period 1968-2009. Monitoring the evolution of rainfall, temperatures and evapotranspiration in the Mikkes basin during the period 1968-2009 shows that rainfall decreases, temperature and evapotranspiration increase from South to North of the basin (spatial drought). Also, these climatic indicators highlight a decrease in rainfall, increase in temperatures and evapotranspiration after 1980 (temporal drought). Flow deficit of Mikkes River between the period 1968-1979 and 1980-2009 is around 76%. This high River flow may due to the drought which the region has experienced since 1980 and also to the overexploitation of groundwater resources to satisfy water demands. The Mikkes basin is suffering severe depletion of groundwater piezometric levels, especially in the confined aquifer.
منابع و مأخذ:
ABHS (2008) Towards a program of measures for the Sebou basin: Pressures - Impacts - Objectives – Measures, Preliminary report of Water Sebou project -April 2008- (in French) 56p.
Agoumi A (2003) Vulnerability of North African countries to climatic changes: adaptation and implementation strategies for climatic change in Developing 475 Perspectives on Climate Change: Issues and Analysis from Developing Countries and Countries with Economies in Transition, International Institute for Sustainable Development & Climate Change Knowledge Network, Winnipeg, Manitoba, Canada, p14.
Bader J, Latif M (2003) The impact of decadal-scale Indian Ocean Sea surface temperature anomalies on Sahelian rainfall and the North Atlantic Oscillation, Geophysical Research Letters 30(22): 2169.
Belhassan K (2010) Drought - piezometric level of the groundwater aquifers: Mikkes basin (Morocco), Fourteenth International Water Technology Conference 14: 25-41.
Belhassan K (2011) Relationship between River Flow, Rainfall and Groundwater pumpage in Mikkes Basin (Morocco), Iranian Journal of Earth Sciences 3(2): 98 -107.
Belhassan K (2020) Relationship Between River and Groundwater: Water Table Piezometry of the Mikkes Basin (Morocco), International Journal of Water Resources and Environmental Sciences 9(1): 01-06.
Belhassan K (2021) Water Scarcity Management. In: Vaseashta A., Maftei C. (eds) Water Safety, Security and Sustainability. Advanced Sciences and Technologies for Security Applications. Springer, Cham.
Belhassan K, Hessane MA, Essahlaoui A (2009) Exchange Groundwater - River: Stream Mikkes Basin (Morocco), Research Journal of Earth Sciences 1(2): 51-61.
Belhassan K, Hessane MA, Essahlaoui A (2010) Interaction between surface water and groundwater in the Mikkes basin Morocco (in French), Hydrological Sciences Journal 55(8): 1371-1384.
Driouech F (2009) Distribution of Moroccan winter precipitation “climate change context”: downscaling and uncertainties, Doctoral thesis, University of Toulouse, France (in French), 164p.
Ghasem Shirazi B, Bakhshandeh L, Yazdi A (2014) Paleoecology of Upper Cretaceous Sediments in Central Iran, Kerman (Bondar- e Bido Section) Based on Ostracods. Marine Science 4 (2): 49-57.
Giannini A, Saravanan R, Chang P (2003) Oceanic forcing of Sahel rainfall on interannual to interdecadal time scales, Journal of Science 302: 1027–1030.
Goula BTA, Savane I, Konan B, Fadika V, Kouadio GB (2006) Impact of climate variability on the water resources of the N’zo and N’zi basins -humid tropical Africa- (in French), Journal of Vertigo l7(1): 1-12.
Hoerling M, Hurrell J, Eischeid J, Phillips A (2006) Detection and attribution of twentieth-century northern and southern African rainfall change, Journal of Climate 19: 3989-4008.
Jehangir Khan M, Ghazi S, Mehmood M, Yazdi A, Naseem AA, Serwar U, Zaheer A, Ullah H (2021) Sedimentological and provenance analysis of the Cretaceous Moro formation Rakhi Gorge, Eastern Sulaiman Range, Pakistan, Iranian Journal of Earth Sciences 13 (4), 252-266.
Li LJ, Zhang L, Wang H, Meng X (2007) Assessing the impact of climate variability and human activities on streamflow from the Wuding river basin in China, Journal of Hydrological Processes 21: 3485-3491.
McCabe GJ, Betancourt JL, Gray ST, Palecki MA, Hidalgo HG (2008) Associations of multi-decadal sea-surface temperature variability with US drought, Journal of Quaternary International 188(1): 31-40.
Méndez M, Magaña V (2010) Regional aspects of prolonged meteorological droughts over Mexico and Central America, Journal of Climate 23(5): 1175-1188.
Orellana R, Espodos C, Gonzcilcz-Iturbe JA (2002) Applications of modified Gaussen ombrothermic diagrams, in the Yucatan Peninsula, En. Sanchez Crispin, A. (editor). Mexico in its unity and territorial diversity. National Institute of Geography, Statistics and Informatics (INEGI) and Mexican Society of Geography Aguaselietes (in Spanish), 60-73.
Paturel JE, Servat E, Kouame B, Lubes H, Ouedraogo M, Masson JM (1997) Climatic variability in humid Africa along the Gulf of Guinea. Part II: An integrated regional approach, Journal of Hydrology 91: 16-36.
Rezapour Tabari MM, Yazdi A (2014) Conjunctive use of surface and groundwater with inter-basin transfer approach: case study Piranshahr, Water resources management 28, 1887-1906
Rossillon J (1984) Dynamics of populations of benthic macro-invertebrates in a Salmonicultural river (Samson): Approach to regulatory factors, Doctoral thesis Es-Sciences, University of Notre Dame de Paris, Nemur, 199p.
Thiessen AH (1911) Precipitations averages for large areas, Journal of Monthly Weather Review 39(7): 1082-1084.
Thornthwaite CW (1948) A rational approach to climate classification (in French), Journal of Geographical Review 38: 55-94.
Trenberth K E, Smith L, Qian T, Dai A, Fasullo J (2007) Estimates of the Global Water Budget and Its Annual Cycle Using Observational and Model Data, Journal of Hydrometeorology 8(4): 758–769.
Vaseashta A (ed) (2015) Life cycle analysis of nanoparticles: risk, assessment, and sustainability, DEStech Publishers, 404p.
Wilcox BP, Seyfried MS, Breshears D (2003) Water Balance on Rangelands, Encyclopedia of Water Science 791-794.
Zhang Y, Guan D, Jin C, Wang A, Wu J, Yuan F (2014) Impacts of climate change and land use change on runoff of forest catchment in northeast China, Journal of Hydrological Processes 28(2): 186-196.