|Pays, régions, bassins fluviaux|
|Ressources en eau|
|Usages de l'eau|
|Irrigation et drainage|
|Ensembles de données|
|Cartes et données spatiales|
Info pour les médias
|Visualisations et infographies|
|ODD Cible 6.4|
|Year: 2009||Revision date: --||Revision type: --|
|Regional report:||Water Report 34: English or Arabic|
The Asi-Orontes River Basin is a transboundary basin with a total area of about 24 660 km2 of which 69 percent is located in the Syrian Arab Republic, 23 percent in Turkey and 8 percent in Lebanon (Lehner et al, 2008) (Table 1). The Asi-Orontes is the only river in the region flowing in northern direction, draining from western Asia to the Levant coastline of the Mediterranean Sea. The river rises in the mountains of Lebanon and flows 40 km in Lebanon to continue into the Syrian Arab Republic for about 325 km before arriving in Turkey for its last reach of 88 km to the Mediterranean Sea (UNESCO-IHE, 2002). The river rises in the great springs of Labweh on the east side of the Bekaa Valley and it runs in a northern direction, parallel with the coast, falling 600 m through a rocky gorge. Leaving this, it expands into the Qattinah Lake, having been dammed back in antiquity. The valley now widens out into the rich district of Hama, below which lie the broad meadow-lands of Amykes, containing the sites of ancient Apamea. This central Asi–Orontes valley ends at the rocky barrier of Jisr al-Hadid, where the river is diverted to the west and the plain of Antioch opens. Two large tributaries from the north, the Afrin and Karasu, reach it here through the former Lake of Antioch or Lake Amik, which is now drained through the artificial Nahr al-Kowsit channel. Passing north of the modern Antakya (ancient Antioch) the Asi–Orontes plunges southwest into a gorge and falls 50 m in 16 km to the sea just south of the little port of Samandagi.
The average annual precipitation in the basin is estimated at 644 mm, although it varies all along the basin area. Annual average temperature of the entire Asi–Orontes River Basin is estimated at 16 ºC. Average temperature in the basin in January is 6 ºC, although it can drop to –1 ºC in the coldest places of the basin. In August, the average temperature reaches 25 ºC, rising to 28 °C in the hottest places (New et al, 2002). In the Lebanese part of the Asi–Orontes Basin, the climate is semi-arid to arid, with annual rainfall below 400 mm (Estephan et al, 2008). In the Syrian part, the western mountains receive precipitation ranging from 600 to 1 500 mm, while in the eastern parts of the basin it is much lower, ranging from 400 to 600 mm (FAO, 2006). The Turkish part of the basin is a transition zone between the Mediterranean and Eastern Anatolian climatic zones. While a southeastern climate prevails in the eastern part of this basin, the western parts is dominated by a Mediterranean climate.
The Asi–Orontes River and its tributaries collect the runoff from the highlands and plateau areas situated on both sides of the rift valley. The average annual flow of the river is estimated at 2 400 million m3, but the surface water amount in the basin has been re-estimated at 1 110 million m3 (FAO, 2006). The Al-Azraq spring is a very important tributary to the Asi–Orontes with an annual flow of more than 400 million m3. There are several bid springs: Al Ghab, Al Rouj, and Al Zarka (FAO, 2006).
The annual flow from Lebanon to the Syrian Arab Republic is 415 million m3, of which an informal agreement between these two countries attributes 80 million m3 to Lebanon and the rest to the Syrian Arab Republic. The natural annual flow from the Syrian Arab Republic to Turkey is estimated at 1 200 million m3, while the actual flow amounts to 12 million m3.
The intensive use of groundwater by agriculture in the last decade has resulted in depletion of the water storage in the aquifers, lowering of the groundwater table and considerable reduction of the spring yield. The average annual discharge of 26 springs in Al Ghab valley dropped from 18.5 m3/s in the period 1965–71 to 9.7 m3/s in 1992–93 and declined steadily to 4.2 m3/s in 1995–96. The amount of groundwater in the Syrian part of the Asi–Orontes Basin is estimated at 1 607 million m3; most of it flows as springs (1 134 million m3) and the rest (473 million m3) is stored into aquifers and withdrawn from wells for irrigation and water supply.
Water quality is good in the headwaters, while due to anthropogenic inputs associated with agricultural, urban, and industrial activities it deteriorates in the middle section of the river.
The total area equipped for irrigation in the Asi–Orontes River Basin is estimated at 300 000–350 000 ha, of which approximately 58 percent in the Syrian Arab Republic, 36 percent in Turkey, and 6 percent in Lebanon. Agricultural water withdrawal is approximately 2.8 km3.
The Asi–Orontes Basin is an important agricultural area, contributing to the regional economy.
In the Lebanese Bekaa valley, the most important crops are fruits, vegetables, field crops, and forests and rangeland. However, poor management of natural resources and poor integration of production systems produce low farm income and unsustainable farming (Estephan et al, 2008). To obtain water for irrigation, two water regulators have been placed in Lebanon on the Asi–Orontes (El-Fadel et al, 2002).
In the Syrian part of the basin the total area irrigated increased from 155 300 ha in 1989 to around 215 000 ha in 2008. The expansion of irrigation using groundwater has been most intensive in the Al Ghab valley and the Mohafazat of Idleb. In the Al Ghab region, the areas irrigated with groundwater have increased and the areas irrigated with surface water have decreased. The annual amount of groundwater used for water supply, irrigation and industry is more than 1 607 million m3, while the annual renewable amount in aquifers is less than 473 million m3, meaning an over-abstraction of 1 134 million m3 (FAO, 2006).
In the Syrian Arab Republic, regulation of the Asi–Orontes River flow to increase its irrigation capacity began with the reconstruction of the ancient Qattinah Dam in 1937, completed in 1976, and the construction of the dams at Rastan and Mhardeh on the main river stream in 1960, the first large dams built in the Syrian Arab Republic. These reservoirs control about 12 600 km2 of the Asi–Orontes drainage basin upstream of Mhardeh. The total capacity of the three reservoirs (495 million m3) represents about 45 percent of the estimated average annual flow yield. Until 2002 the dams built in the Syrian part of the basin numbered 41, with total a reservoir capacity of 741 million m3, all built on tributaries of the Asi–Orontes River. Among the dams with large reservoir capacity is the Zeyzoun Dam (71 million m3) which had been damaged in 2002. The Zeita Dam, one of the most recently built dams, will have a total capacity of 80 million m3 (SPC, 2009).
In Turkey, the Lake of Antioch or Lake Amik was a large freshwater lake in the Asi–Orontes River Basin in Hatay Province which is now drained through the artificial channel Nahr al-Kowsit. Sedimentary analysis suggests that Lake Amik was formed, in its final state, in the past 3000 years by episodic floods and silting up of the outlet to the Asi–Orontes. This dramatic increase in the lake’s area displaced many settlements; the lake became an important source of fish and shellfish for the surrounding area and the city of Antioch. The lake was drained during a period from the 1940s–1970s. The most important dams located on the Turkish side of the basin are the Karamanli Dam and the Yarseli Dam.
Table 2 shows the large dams in the Asi–Orontes River Basin, i.e. dams with a height of more than 15 metres or with a height of 5–15 metres and a reservoir capacity greater than 3 million m3 according to the International Commission on Large Dams (ICOLD).
Mainly non-navigable and of relatively little use for irrigation, the Asi–Orontes derives its historical importance from the convenience of its valley for traffic from north to south; roads from the north and northeast, converging at Antioch, follow the course of the stream up to Hims, where they built the Al-Rastan Dam, before forking to Damascus and to the Syrian Arab Republic and the south. The Asi–Orontes has long been a boundary marker. For the Egyptians it marked the northern extremity of Amurru, east of Phoenicia. For the Crusaders in the 12th century, the Asi–Orontes River became the permanent boundary between the Principality of Antioch and that of Aleppo.
The Syrian Arab Republic has been using 90 percent of the total flow, which reaches an annual average of 1 200 million m3 at the Turkish-Syrian border. Out of this total capacity, only a meagre 12 million m3 enter Turkey after heavy use by the Syrian Arab Republic.
In August 1994, the Lebanese and Syrian governments reached a water-sharing agreement on the Asi–Orontes River, according to which Lebanon receives 80 million m3/year and the remaining 335 million m3 are for the Syrian Arab Republic if the river’s flow inside Lebanon is 400 million m3 or more during that given year. If this figure falls below 400 m3, Lebanon’s share is adjusted downwards, relative to the reduction in flow. Wells in the river’s catchments area that were already operational before the agreement are allowed to remain operational, but no new wells are permitted.
In 2009 Turkey and the Syrian Arab Republic have agreed in principle to develop the “Asi Friendship Dam”, to be built on the Asi–Orontes River on the border between the Syrian Arab Republic and Turkey. The dam is expected to be approximately 15 m high with a capacity of 110 million m3. Of that total, 40 million m3 will be used to prevent flooding and the rest for energy production and irrigation. The idea to build a shared dam on the Asi–Orontes River has been discussed over the years between Turkey and the Syrian Arab Republic, but political differences between the countries held them back until now.
Table 3 shows the main historical events in the Asi–Orontes River Basin.
Bridgland D.R, Philip G., Westaway R. and White M. 2003. A long Quaternary terrace sequence in the Orontes River valley, Syria: A record of uplift and of human occupation. Current science, Vol. 84, No. 8, 25 April 2003.
Bucks, D.A. 1993. Micro-irrigation world wide usage report.
Comair, F.G. 2008. Gestion et hydrodiplomatie de l’eau au Proche-orient.
Dogan Y.P. 2009. Turkey, Syria cooperate on water front. Today’s Zaman. 20 March 2009.
DSI (General directorate of state hydraulic works). XXst Regional Directorate of State Hydraulic works - Kahramanmaras.
Estephan C., Nimah M.N., Farajalla N., Karam F. 2008. Lebanon. Rural Development Project. The Upper Bekaa valley of Lebanon. Orontes River Basin.
FAO. 1995. Irrigation in Africa/L’irrigation en Afrique en chiffres. FAO Water Report No. 7. Rome.
FAO. 1997a. Irrigation in the Near East Region in figures. FAO Water Report No. 9. Rome.
FAO. 1997b. Irrigation in the countries of the former Soviet Union in figures. FAO Water Report No. 15. Rome.
FAO. 1997c. Irrigation potential in Africa - a basin approach. FAO Land and Water Bulletin No. 4. Rome.
FAO. 1999. Irrigation in Asia in figures. FAO Water Report No. 18. Rome.
FAO. 2003. Review of world water resources by country. FAO Water Report No. 23. Rome.
FAO. 2004. Support to the drafting of a national Water Resources Master Plan.
FAO. 2005. Irrigation in Africa in figures – AQUASTAT survey 2005. FAO Water Report No. 29. Rome.
FAO. 2006. Orontes basin (Al Assi).International Symposium on irrigation modernization: constraints and solutions. Damascus, Syria. 28–31 March 2006.
FAO. 2008a. FAOSTAT – database. Available at http://faostat.fao.org/.
FAO. 2008b. AQUASTAT – database. Available at http://www.fao.org/nr/aquastat/.
Gleick, P.H., ed. 1993. Water in crisis: a guide to the of world’s freshwater resources. New York, USA, Oxford, UK, Oxford University Press for Pacific Institute. 473 pp.
Gleick, P.H., ed. 2006. The world’s water 2006-2007: the biennial report on freshwater resources. Washington, DC, Island Press.
ICID (International Commission on Irrigation and Drainage). 2005. Sprinkler and micro-irrigated area in some ICID member countries. Available at http://www.icid.org.
IPTRID (International Programme for Technology and Research in Irrigation and Drainage) /FAO. 2003. The irrigation challenge - increasing irrigation contribution to food security through higher water productivity canal irrigation systems. Issue paper No. 4.
Khater, A.R. 2003. Intensive groundwater use in the Middle East and North Africa In R. Llamas & E. Custodio, eds. Intensive use of groundwater challenges and opportunities. Abingdon, UK, Balkema. 478 pp.
Lehner, B., Verdin, K., Jarvis, A. 2008. New global hydrography derived from spaceborne elevation data. Eos, Transactions, AGU, 89(10): 93-94. HydroSHEDS. Available at the following link: http://www.worldwildlife.org/hydrosheds and http://hydrosheds.cr.usgs.gov.
Lowi, M. After 1996. Political and institutional responses to transboundary water disputes in the Middle East.
L'vovitch, M.I. 1974. World water resources and their future. Russian ed. Mysl. Moscow. Translation in English by R.L. Nace, American Geological Union, Washington, 1979. 415 pp.
Milich, L and Varady, G. 1998. Openness, sustainability, and public participation in transboundary river-basin institutions. The Israel-Jordan Joint Water Committee (IJJWC)
Möllenkamp S. 2003. Transboundary river basin management - new challenges in EU 25 and beyond.
New, M., Lister, D., Hulme, M. and Makin, I. 2002. A high-resolution data set of surface climate over global land areas. Climate Research 2. Available at following link: http://www.cru.uea.ac.uk/cru/data/hrg.htm.
OSU (Oregon State University). 2002. International river basins of the world.
Slim K., Saad Z, El-Samad O., Kazpard V. Chemical and algological characterization of surface waters in the Orontes River (Lebanon) in a semiarid environment.
Sofer A., Rosovesky M. and Copaken N. 1999. Rivers of fire: the conflict over water in the Middle East.
UN (United Nations). 2006. The UN World Water Development Report II: Water, a shared responsibility. UNESCO / Berghahn Books.
UNDG (United Nations Development Group). 2005. The national water master plan – Phase 1 Water Resources Assessment. 26 pp.
UNDP (United Nations Development Programme). 2008. Human Development Index. Available at http://hdr.undp.org).
UNEP. 2003. GEO Year Book 2003. Theme: Freshwater.
UNESCO-IHE (Institute for water education). 2002. From conflict to cooperation in international water resources management: challenges and opportunities. Institute for Water Education Delft, The Netherlands.
UNICEF (United Nations Children's Fund). 2005. Statistics by country. Available at http://www.unicef.org
UNICEF / WHO (World Health Organization). 2008. Joint Monitoring Programme (JMP) for water and sanitation. Available at http://www.wssinfo.org.
Vermooten, J.S.A, Kloosterman F.H. After 2002. The reaction of the groundwater system of the Syrian Orontes basin to stresses from large scale groundwater pumping.
WHYMAP (World-wide hydrogeological mapping and assessment programme). 2008. Groundwater resources of the world.
WHO (World Health Organization). 2005. World malaria report 2005.
World Bank. 1998. International watercourses: enhancing cooperation and managing conflict.
World Bank. 2007. Making the most of scarcity.
World Bank. 2008. Indicators of world development.
World Resources Institute. 1994. World resources 1994-1995. A guide to the global environment. Oxford University Press for WRI/UNEP/UNDP. 400 pp.
World Resources Institute. 2003. World resources 2002-2004. Decisions for the earth: balance, voice, and power.
Yavuz, Ercan. 2008. Turkey, Iraq, Syria to initiate water talks. Today’s Zaman 12/03/2008.
^ haut de page ^
|Citer comme suit: FAO. 2016. Site web AQUASTAT. Organisation des Nations Unies pour l'alimentation et l'agriculture. Site consulté le [aaaa/mm/jj].|
|© FAO, 2016Questions ou commentaires? firstname.lastname@example.org|
|Votre accès à AQUASTAT et l’utilisation de toute information ou donnée est soumis aux termes et conditions spécifiés dans le User Agreement.|