Water resources management in El Salvador explained

Country:El Salvador[1]
Withdrawals Year:2000
Domestic:25%
Agriculture:59.4%
Industry:15.6%
Renewable:17.75 km3
Surface Water Produced:25 km3
Groundwater Recharge:6.15 km3
Overlap:6 km3
Renewable Resources Pc:2,755 m3/year
Ramsar:1,333 km2 (2010)
Hydropower:36%

Water resources management in El Salvador is characterized by difficulties in addressing severe water pollution throughout much of the country's surface waters due to untreated discharges of agricultural, domestic and industrial run off. The river that drains the capital city of San Salvador is considered to be polluted beyond the capability of most treatment procedures.

El Salvador has ample groundwater and partly relies on these supplies for domestic purposes. Deforestation has ravaged the country to the point that very little primary forest remains. This has led to substantial difficulties in managing stormwater when hurricanes and tropical storms make landfall.

Torrential rain leads to deadly floods and mudslides that have claimed many lives in El Salvador. A growing urban population coupled with high levels of water losses in urban centers is also challenging water institutions that are not well coordinated. This leads to inefficient water resources management.

Water management challenges

Water pollution

The Acelhuate River is an important drainage system for El Salvador's capital, San Salvador, and is severely contaminated with heavy metals along with domestic and industrial waste. This water is considered a biohazard, and the contamination is so severe that it is rendered untreatable by treatment methods such as reverse osmosis. Contaminated water from the Acelhuate River flows directly into the Cerron Grande reservoir.[2]

The Cerrón Grande reservoir is overloaded with sewage and industrial waste. In a 2004 study, the El Salvador Ministry of Environment found that the waste is coming from 54 industrial plants, 55 coffee processing plants, seven sugar mills, and 29 sewer systems discharging directly into the reservoir. Cerrón Grande dam was built in 1974 to drive El Salvador's largest hydroelectric project, and the 135 km2 reservoir collects some 3,800 tones of excrement each year from the sewage pipes, as well as factory effluents consisting of heavy metals such as chromium and lead.[3]

The sedimentation volumes in the Cerron Grande Reservoir are dangerously high also and estimated to be as high as 7 million m3 per year which gravely impacts the health of the reservoir.[2] Many shallow aquifers are becoming contaminated from the severe surface pollution, and this is critically challenging as deeper wells are more relied upon to provide potable water.

In El Salvador, rivers and streams in the principal agricultural areas are highly polluted by pesticides, particularly by DDT in cotton cultivations in the south-eastern coastal plains. Concentrations of 3.15 mg of DDT per litre of water have been discovered in the Río Grande de San Miguel.

Flooding and stormwater

El Salvador sits directly in the path of tropical storms and hurricanes as evidenced by Hurricane Mitch in 1998 causing US$400 million in damage. Hurricane Stan in 2005 caused considerable flooding throughout El Salvador, resulted in 67 deaths, and displaced more than 50,000 people. Damages from Stan were estimated at US$355 million. There was a tropical storm in 2008 that also led to major flooding and mudslides and killed 199.[4]

Another determining factor in the severe flood waters that plague El Salvador is deforestation. El Salvador is the second most deforested country in Latin America after Haiti. Much of El Salvador's tree cover has been removed, leaving the country vulnerable to flash flooding. Only an estimated 2 per cent of the tree cover that existed before the 10-year civil war remains. Almost 85 percent of its forested cover has disappeared since the 1960s and less than 6,000 hectares are classified as primary forest.[5]

Urbanization

The urbanized population in El Salvador was 61% in 2008 with an increase of 2% each year.[6] In the case of San Salvador, the urbanized surface of the metropolitan area has increased almost exponentially, from 6.8 km2 in 1935 to 91.5 km2 in 2000. This has mainly taken place in the largest aquifer recharge areas. Because of this, the areas with the highest rate of infiltration have been reduced, whereas the areas with a low infiltration rate of 0.05 mm/hour have increased by the same proportion.

Water resource base

Lempa River
Length:422km (262miles)
Discharge1 Avg:362m3/s
Source1 Location:Sierra Madre, Guatemala
Source1 Elevation:1200m (3,900feet)
Mouth:Pacific Ocean
Basin Size:18246km2

It is estimated that El Salvador has 17.3 km3 of water resources per year. Approximately 67% or 11.6 km3 of this water is surface water. The remaining 5.7 km3 are found in groundwater which is heavily relied upon because surface water is generally severely polluted. Precipitation levels are the most significant in the higher elevations varying from about 2, 286 mm in the mountain ranges down to 1,448 mm in coastal plains. About 95% of the rainfall occurs from May to October with frequent and severe droughts occurring during the drier months.[2] Around 84% of the surface runoff takes place during the rainy season (May–October) while the remaining 16% will run off during the dry season.[7]

Groundwater and surface water resources

El Salvador counts nearly 360 rivers that connect to form ten hydrographic regions. There are four primary lakes in El Salvador including the Ilopango (72 km2), Guija (44 km2), Coatepeque (24.8 km2), , Olomega (24.2 km2) and four reservoirs created by hydroelectric dams discussed in more detail below. El Salvador also obtains about 7.5 km3 of surface water per year from neighboring Honduras and Guatemala.[7] The Cerrón Grande Reservoir, known locally as Lake Suchitlán, is the largest body of fresh water in El Salvador.[8]

The Lempa River watershed dominates El Salvador covering half of the country at 10, 255 km2 and draining 6, 214 million m3. The Lempa is 422 km long and originates in the Sierra Madre and the Sierra del Merendón in southern Guatemala. The river flows in Honduras for 31 km before entering El Salvador in northwest.

Groundwater is heavily relied upon for water supply as a result of polluted surface water, and sufficient supplies of fresh groundwater are available throughout most of the country. Groundwater recharge from infiltration is estimated at 6.15 km3 per year whereby 5.97 km3 is considered base flow that serves to recharge surface waters and therefore has the possibility of being extracted. The remaining unused water passes down through the river system and discharges into the Pacific Ocean. The best aquifers are located in coastal areas and valleys of the central plateau where substantial groundwater aquifers are located at depths of 10–100 meters.[7]

Table: Principal characteristics in hydrological regions of El Salvador.

Hydrographic RegionPrimary riversSurface Area (km2) Annual Runoff (million m3)Rainy season annual runoff (million m3)Dry Season annual runoff (million m3)
A Lempa10, 2556, 2145, 217836
B Paz929466358107
CSacramento, Sunza 65936931751
D San Pedro, Sonsonate, Banderas 875776654123
EMaridinga, Tihuapa 1,14635931050
F Comalapa, Guayabo 1,71788680495
G Afluentes de la Bahia de Jiquilisco 958618502115
H Grande de San Miguel 2, 2501,161985175
I Afluentes del Golfo de Fonseca 80429929633
J Sirama y Guascorán 1,34847942356
SubTotal20,94111,6279.8671,642
Total with Guatemala and Honduras runoff totals added (regions A, B, J)31,841 17,76815,0172,632
Source: FAO 2000

Water resources management by sector

The average per capita availability of water in El Salvador is less than 2,800 m3/year. Per capita annual extraction is 118 m3 representing about 4.3% of available supplies. Agriculture uses about 60%, domestic needs are around 24%, and industrial usage is 16%.[9]

Water coverage and usage

See main article: Water supply and sanitation in El Salvador.

Access to an improved water source in El Salvador was estimated at 76% in 2006. Urban access was 90%, including about 13% lacking a piped connection to the house. Access in rural areas in 2006 was 50%, however only 38% of this total had a piped connection to the house. Most water in rural areas is drawn from groundwater wells.[10]

Irrigation and drainage

Potential surface area for irrigation if only considering soil type is around 676000acres; however, when adequate availability of water is also considered, the potential surface area for irrigation is about 500000acres. Approximately 56% of water available for irrigation is drawn from surface water while the rest is supplied from groundwater. The highest potential for irrigation is located in the coastal plains where the best groundwater is located. About 24% of the total potential area is classified as having "good" potential, while 60% is classified as having a "moderate" potential, and finally about 15% is classified as having potential with substantial limitations.[7]

The private sector for irrigation has grown substantially since 1950 when only 4000acres were under irrigation by the private sector. By 1960, there were 40000acres irrigated by the private sector and in 1995, 57000acres were being irrigated under private control. A concerted effort to develop the irrigation sector between 1966 and 1991 was put forth by the Ministry of Agriculture (MAG) through their General Directorate of Irrigation and Drainage. MAG enacted irrigation districts in Zapotitán (7,400 acres), and Atiocoyo (9,760 acres) with an investment of US $24.7 million and later developed the Lempa-Acahuapa district at a cost of US $21.2 million.[7]

Since 1975, growth in private sector irrigation has stabilized where grass crops have been replaced with higher value crops with a larger profit margin. The distribution of publicly managed irrigation are located mostly in the Sonsonate, Sensunapán, Banderas, and San Pedro watersheds. Public irrigation projects are also prevalent in other areas where good water and soil are located such as the Lempa River, Titihuapa, Sucio, Torola, Grande, and Suquiapa basins. The beneficiaries of public irrigation are organized into 36 associations.[7] Total surface area with irrigation drainage problems was estimated at 370658acres where most of this land is located in coastal plains. These coastal regions are home to many mangroves and marshes, therefore land remains saturated. There have been successful past efforts to pump off or convey excess water left behind after the rainy season. While drainage is a problem, salinity problems have not been widely detected in the soil.[7]

Hydroelectricity

See main article: Electricity sector in El Salvador.

Hydroelectric potential is estimated at 1,889 MW where 1,409 MW of this potential is on the Lempa River. However, only 21% of the potential of the Lempa River is utilized.[2] CEL (Comisión Hidroeléctrica del Río Lempa) is a public entity that generates over 90% of the hydroelectric output of El Salvador. Four projects on the Lempa River constitute all of the hydroelectricity generation in El Salvador and account for 41% of the total electricity produced in the country.

Projects include:[11]

New Hydroelectric projects include:

Legal and institutional framework

Twenty-five agencies share responsibility for overseeing the water resources of El Salvador. There is currently no mechanism for coordinating their efforts, which creates duplication and inefficient use of resources. The El Salvador Congress charged the Secretaria Ejecutiva del Medio Ambiente (SEMA) with the responsibility of setting the national environmental regulatory policy and to also enforce its compliance. As of 1998, land use regulations rested with the Administracion Nacional de Acueductos y Alcantarillados (ANDA) but these regulations were lacking the necessary enforcement tools. Although there is a general lack of enforcement, laws for regulating discharge of domestic and industrial wastes exist, but only for new industries.[2]

Legal framework

Institutional framework

Cooperation with Guatemala and Honduras

The upper watershed of the Lempa River is shared by Guatemala, El Salvador, and Honduras, as outlined in the Trifinio Plan, which was established and signed by the aforementioned countries to address economic and environmental problems in the Lempa River basin, and foster cooperation and regional integration. The Trifinio plan or treaty sought to provide a more viable and effective alternative to unilateral development thereby concentrating on greater multinational integration.

The Trifinio region covers an area of about 7,500 km2 in the border areas of Honduras, Guatemala, and El Salvador. The region is made up of 45 municipalities whereby 22 belong to Honduras within the departments of Ocotepeque and Copán, 15 are situated in Guatemala corresponding to the departments of Chiquimula and Jutiapa, and 8 are in the departments of Santa Ana and Chalatenango in El Salvador.[22] In the early stages of the Trifinio Plan's development, the commission studied three international river basins, and in 1987 they developed a new plan involving the Lempa River Basin, the Ulúa River, and the Motagua River. However, the Motagua and Ulúa rivers were eventually dropped, leaving the Lempa River as the Trifinio Plan's primary focus.

In 1996, the governments of El Salvador, Honduras, and Guatemala signed an agreement to cooperate on formulating a development plan for their shared boundary region. In 1998, the signatories completed the Central American Action Plan for integrated development of water resources to combat water pollution and promote the sustainable development of Central America's shared water resources by jointly developing watershed management plans. These plans included reforestation efforts which concluded in the second phase of the Trifinio Plan in 1997. By 2000 new efforts were initiated to begin managing the upper Lempa River Basin.[23]

Ramsar wetland sites in El Salvador

Lake Olomega
Pushpin Map:El Salvador#Central America
Location:South-Eastern El Salvador
Inflow:Río Grande de San Miguel
Basin Countries:El Salvador

Wetlands in El Salvador serve many crucial water management services such as flood control, groundwater replenishment, natural water purification, and are also productive fish and shrimp ecosystems. The wetlands within the Bahía de Jiquilisco for example are primarily mangrove forests that serve to protect against tidal surges when hurricanes and tropical storms strike. Without these forests, tidal surges would lead to the salination of fresh groundwater further inland which would contaminate supplies for domestic and agricultural uses.

The Ramsar Convention wetland sites:[24]

Potential climate change impacts

The Global Climate Risk Index[25] constructed for the period between 1997 and 2006 and covering both human and economic impacts, ranks El Salvador the 30th most at risk country in the world.[26] According to climate scenarios developed by researchers for El Salvador, the following (below) climate changes are likely to occur between 2070 and 2099[27] and adversely impact groundwater, hydropower output, and flood control management efforts.

The Drought Response and Mitigation Project in El Salvador, implemented by the Red Cross in 2002 helped to mitigate the effects of droughts affecting the country. The objective of this initiative was to increase the capacity of subsistence farmers in the east of the country to better respond to adverse effects of climate conditions, by providing technical assistance to diversify and market crops, reforestation using fruit trees, use of organic fertilizers and small scale irrigation systems.[28]

See also

External links

Notes and References

  1. FAO Aquastat 1988 - 2008
  2. Web site: Water Resources Assessment of El Salvador. U.S. Army Corps of Engineers. U.S. Army Corps of Engineers. 1998 . 2010-03-19.
  3. News: Contaminated Salvador lake is mystery bird magnet. Barrera, A.. Reuters. 2010-03-19. 2007-05-17.
  4. Web site: Background Note: El Salvador. US Department of State. US Department of State. 2010 . 2010-03-25.
  5. News: El Salvador flood disaster worsened by deforestation. https://web.archive.org/web/20100324153126/http://www.independent.co.uk/environment/el-salvador-flood-disaster-worsened-by-deforestation-509617.html. dead. March 24, 2010. Taylor J.. The Independent. 2010-03-25. London. 2005-10-05.
  6. Web site: Country profile: El Salvador. CIA. CIA. 2008. 2010-03-22.
  7. Web site: EL Salvador. FAO. FAO. 2000. 2010-03-20.
  8. Web site: Descripción de embalses de El Salvador . Organismo Internacional Regional de Sanidad Agropecuaria (OIRSA). 2005 . 2009-05-04 .
  9. Web site: Groundwater in Central America: Its Importance, Development and Use, with Particular Reference to Its Role in Irrigated Agriculture. BALLESTERO M. . REYES V. . ASTORGA Y. . International Water Management Institute. 2000 . 100–128. 2010-03-22.
  10. Web site: Estimates for the use of Improved Drinking-Water Sources . UNICEF's Joint Monitoring Program (JMP) . UNICEF . 2010 . 2010-03-23 . dead . https://web.archive.org/web/20100322210156/http://wssinfo.org/datamining/maps.html . March 22, 2010 .
  11. Web site: Central Hidroeléctrica Cerrón Grande . Comisión Ejecutiva Hidroeléctrica del Río Lempa (CEL). 2007. 2010-03-20.
  12. Web site: Proyecto Hidroeléctrico El Cimarrón . CEL . 2010-03-19 .
  13. Web site: LEY DE LA ADMINISTRACION NACIONAL DE ACUEDUCTOS Y ALCANTARILLADOS. Supreme Court of El Salvador. Supreme Court of El Salvador. 1961. 2010-03-22.
  14. Web site: Approval by a Government Board. Government of El Salvador. Government of El Salvador. 2007. 2010-03-22.
  15. Web site: Administración Nacional de Acueductos y Alcantarillados. ANDA. ANDA. 2010. 2010-03-20. es.
  16. Web site: MINISTERIO DE AGRICULTURA Y GANADERÍA DE EL SALVADOR. DGFCR. 2010. 2010-03-20. es.
  17. Web site: Comisión Ejecutiva Hidroeléctrica del Río Lempa. CEL. CEL. 2010. 2010-03-20. es.
  18. Web site: Comisión Ejecutiva Hidroeléctrica del Río Lempa. SNET. SNET. 2010. 2010-03-20. es.
  19. Web site: Ministry of Environment and Natural Resources. MARN. MARN. 2010. 2010-03-20. es.
  20. Web site: Fondo de Inversion Social de El Salvador. FIS. FIS. 2010. 2010-03-23. es.
  21. Web site: Ministerio de Salud Pública y Asistencia Social. MSPAS. MSPAS. 2010. 2010-03-23. es.
  22. Web site: Water Conflict and Cooperation/Lempa River Basin. Artiga R.. UNESCO. 2003. 2010-03-25.
  23. Web site: Environmental Conflicts and Regional Cooperation in the Lempa River Basin The Role of Central America´s Plan Trifinio. López A.. The Environmental Change and Security Project (ECSP) Woodrow Wilson International Center for Scholars. 2004 . 13–15. 2010-03-25.
  24. Web site: The Annotated Ramsar List of Wetlands of International Importance. Ramsar. Ramsar. 2010. 2010-03-22.
  25. Web site: GLOBAL CLIMATE RISK INDEX 2008. Harmeling, S.. Germanwatch. 2007. 2010-03-22.
  26. Web site: Climate Change Aspects in Agriculture El Salvador Country Note. SICA. Central American Integration System (SICA) . 2008. 2010-03-22.
  27. Central America Climate Change: Implications for the Rio Lempa. Maurer, E., Wood, A.. Hydrology and Earth System Sciences. 2008. 10.5194/hessd-5-3099-2008. 2010-03-22. free.
  28. Web site: Drought-resistant agriculture in El Salvador. UNFCCC. UNFCCC. 2003. 2010-03-22.