Array ( [0] => {{Short description|Agricultural artificial application of water to land}} [1] => {{about|irrigation for agriculture and landscapes||}} [2] => {{Redirect|Watering|the river in Germany|Wätering}} [3] => {{Use mdy dates|date=December 2022}}[[File:Fields SW from Sevilla.jpg|thumb|Irrigation of agricultural fields in [[Andalusia]], Spain. Irrigation canal on the left.]] [4] => '''Irrigation''' (also referred to as '''watering''') is the practice of applying controlled amounts of [[water]] to [[land]] to help grow [[crop]]s, [[landscape plant]]s, and [[lawn]]s. Irrigation has been a key aspect of [[agriculture]] for over 5,000 years and has been developed by many cultures around the world. Irrigation helps to grow crops, maintain landscapes, and [[revegetation|revegetate]] disturbed soils in dry areas and during times of below-average rainfall. In addition to these uses, irrigation is also employed to protect crops from [[frost]],{{cite book |last1=Snyder |first1=R. L. |url=http://www.fao.org/docrep/008/y7223e/y7223e00.htm |title=Frost protection: fundamentals, practice, and economics |last2=Melo-Abreu |first2=J. P. |publisher=Food and Agriculture Organization of the United Nations |year=2005 |isbn=978-92-5-105328-7 |volume=1 |issn=1684-8241}} suppress [[weed]] growth in [[grain]] fields, and prevent [[soil consolidation]]. It is also used to cool [[livestock]], reduce [[dust]], dispose of [[sewage]], and support [[mining]] operations. [[Drainage]], which involves the removal of surface and sub-surface water from a given location, is often studied in conjunction with irrigation. [5] => [6] => There are several methods of irrigation that differ in how water is supplied to plants. [[Surface irrigation]], also known as gravity irrigation, is the oldest form of irrigation and has been in use for thousands of years. In [[Irrigation sprinkler|sprinkler irrigation]], water is piped to one or more central locations within the field and distributed by overhead high-pressure water devices. [[Micro-irrigation]] is a system that distributes water under low pressure through a piped network and applies it as a small discharge to each plant. Micro-irrigation uses less pressure and water flow than sprinkler irrigation. [[Drip irrigation]] delivers water directly to the root zone of plants. [[Subirrigation]] has been used in field crops in areas with high water tables for many years. It involves artificially raising the water table to moisten the soil below the root zone of plants. [7] => [8] => Irrigation water can come from [[groundwater]] (extracted from [[Spring (hydrosphere)|springs]] or by using [[Water well|wells]]), from surface water (withdrawn from [[river]]s, [[lake]]s or [[reservoirs]]) or from non-conventional sources like [[reclaimed water|treated wastewater]], [[desalinated water]], [[drainage|drainage water]], or [[fog collection]]. Irrigation can be supplementary to [[rain]]fall, which is common in many parts of the world as [[rainfed agriculture]], or it can be full irrigation, where crops rarely rely on any contribution from rainfall. Full irrigation is less common and only occurs in arid landscapes with very low rainfall or when crops are grown in semi-arid areas outside of rainy seasons. [9] => [10] => The environmental effects of irrigation relate to the changes in quantity and quality of [[soil]] and [[water]] as a result of irrigation and the subsequent effects on natural and social conditions in [[river basin]]s and downstream of an [[irrigation scheme]]. The effects stem from the altered [[Hydrology|hydrological conditions]] caused by the installation and operation of the irrigation scheme. Amongst some of these problems is depletion of underground [[aquifers]] through [[overdrafting]]. Soil can be over-irrigated due to poor [[distribution uniformity]] or [[Irrigation scheduling|management]] [[waste]]s water, chemicals, and may lead to [[water pollution]]. Over-irrigation can cause deep drainage from rising water tables that can lead to problems of irrigation [[Soil salinity|salinity]] requiring [[watertable control]] by some form of [[Drainage system (agriculture)|subsurface land drainage]]. [11] => {{TOC limit|3}} [12] => [13] => == Extent == [14] => [[File:Share of agricultural land which is irrigated, OWID.svg|thumb|Share of agricultural land which is irrigated (2015)]] [15] => [[File:Area Equipped For Irrigation By Region.svg|thumb|Area equipped For irrigation by region]] [16] => In 2000, the total fertile land was 2,788,000 km2 (689 million acres) and it was equipped with irrigation infrastructure worldwide. About 68% of this area is in Asia, 17% in the Americas, 9% in Europe, 5% in Africa and 1% in Oceania. The largest contiguous areas of high irrigation density are found in Northern and Eastern India and Pakistan along the Ganges and Indus rivers; in the Hai He, Huang He and Yangtze basins in China; along the Nile river in Egypt and Sudan; and in the Mississippi-Missouri river basin, the Southern Great Plains, and in parts of California in the United States. Smaller irrigation areas are spread across almost all populated parts of the world.{{cite conference | last = Siebert | first = S. | author2 = J. Hoogeveen, P. Döll, J-M. Faurès, S. Feick, and K. Frenken | title = The Digital Global Map of Irrigation Areas – Development and Validation of Map Version 4 | book-title = Tropentag 2006 – Conference on International Agricultural Research for Development | place = Bonn, Germany | date = 2006-11-10 | url = http://www.tropentag.de/2006/abstracts/full/211.pdf | access-date = 2007-03-14 }} [17] => [18] => By 2012, the area of irrigated land had increased to an estimated total of 3,242,917 km2 (801 million acres), which is nearly the size of India.[https://www.cia.gov/the-world-factbook/countries/world/ The World]. ''[[The World Factbook]]''. [[Central Intelligence Agency]]. The irrigation of 20% of farming land accounts for the production of 40% of food production.{{Cite web|title=On Water|url=https://www.eib.org/en/essays/on-water|access-date=2020-12-07|website=European Investment Bank|language=en}}{{Cite web|title=Water in Agriculture|url=https://www.worldbank.org/en/topic/water-in-agriculture|access-date=2020-12-07|website=World Bank|language=en}} [19] => [20] => === Global overview === [21] => The scale of irrigation increased dramatically over the 20th century. In 1800, 8 million hectares globally were irrigated, in 1950, 94 million hectares, and in 1990, 235 million hectares. By 1990, 30% of the global food production came from irrigated land.[[#refMcNeill2000|McNeill 2000]] pp.180–181. Irrigation techniques across the globe includes canals redirecting surface water,[[#refMcNeill2000|McNeill 2000]] pp.174.[[#refPeterson2016|Peterson 2016]] [[groundwater]] pumping, and diverting water from dams. National governments lead most irrigation schemes within their borders, but private investors[[#refMcNeill2000|McNeill 2000]] pp.153. and other nations, especially the [[United States]],[[#refEkbladh2002|Ekbladh 2002]] pp.337. [[China]],[[#refBosshard2009|Bosshard 2009]]. and European countries like the [[United Kingdom]],[[#refMcNeill2000|McNeill 2000]] pp.169-170. also fund and organize some schemes within other nations. [22] => [23] => By 2021 the global land area equipped for irrigation reached 352 million ha, an increase of 22% from the  289 million ha of 2000 and more than twice the 1960s land area equipped for irrigation. The vast majority is located in Asia (70%), where irrigation was a key component of the green revolution; the Americas account for 16% and Europe for 8% of the world total. India (76 million ha) and China (75 million ha) have the largest equipped area for irrigation, far ahead of the United States o fAmerica (27 million ha). China and India also have the largest net gains in equipped area between 2000 and 2020 (+21 million ha for China and +15 million ha for India). All the regions saw increases in the area equipped for irrigation, with Africa growing the fastest (+29%), followed by Asia (+25%), Oceania (+24%), the Americas (+19%) and Europe (+2%).{{Cite book |title=World Food and Agriculture – Statistical Yearbook 2023 {{!}} FAO {{!}} Food and Agriculture Organization of the United Nations |url=https://www.fao.org/documents/card/en?details=cc8166en |access-date=2023-12-13 |website=FAODocuments | date=2023 |language=en |doi=10.4060/cc8166en| isbn=978-92-5-138262-2 }} [24] => [25] => Irrigation enables the production of more crops, especially [[cash crop|commodity crops]] in areas which otherwise could not support them. Countries frequently invested in irrigation to increase [[wheat]], [[rice]], or [[cotton]] production, often with the overarching goal of increasing self-sufficiency. [26] => [27] => === Example values for crops === [28] => {| class="wikitable" [29] => |+Approximate values of seasonal crop water needs{{cite web |last=Natural Resource Management and Environmental Dept |title=Crops Need Water |url=http://www.fao.org/docrep/S2022E/s2022e02.htm |url-status=live |archive-url=https://web.archive.org/web/20120116073927/http://www.fao.org/docrep/S2022E/s2022e02.htm |archive-date=16 January 2012 |access-date=17 March 2012 |df=dmy-all}} [30] => !Crop [31] => !Crop water needs mm / total growing period [32] => |- [33] => |Sugarcane [34] => |1500–2500 [35] => |- [36] => |Banana [37] => |1200–2200 [38] => |- [39] => |Citrus [40] => |900–1200 [41] => |- [42] => |Potato [43] => |500–700 [44] => |- [45] => |Tomato [46] => |400–800 [47] => |- [48] => |Barley/oats/wheat [49] => |450–650 [50] => |- [51] => |Cabbage [52] => |350–500 [53] => |- [54] => |Onions [55] => |350–550 [56] => |- [57] => |Pea [58] => |350–500 [59] => |} [60] => [61] => == Water sources == [62] => [[File:Bisse.jpg|thumb|[[Bisse d'Ayent|Traditional irrigation channel]] in Switzerland, collecting water from the high Alps]] [63] => [[File:Pump-enabled Riverside Irrigation in Comilla, Bangladesh, 25 April 2014.jpg|thumb|right|Irrigation is underway by [[Pump|pump-enabled]] extraction directly from [[Gumti River (Tripura)|the Gumti]], seen in the background, in [[Comilla District|Comilla]], Bangladesh.]] [64] => [65] => === Groundwater and surface water === [66] => [[File:Vale do São Francisco Pernanbuco.jpg|thumb|Grapes in [[Petrolina]], Brazil only made possible in this [[semi arid]] area by [[drip irrigation]]]] [67] => [68] => Irrigation water can come from [[groundwater]] (extracted from [[Spring (hydrosphere)|springs]] or by using [[Water well|wells]]), from surface water (withdrawn from [[river]]s, [[lake]]s or [[reservoirs]]) or from non-conventional sources like [[reclaimed water|treated wastewater]], [[desalinated water]], [[drainage|drainage water]], or [[fog collection]]. [69] => [70] => While [[floodwater]] harvesting belongs to the accepted irrigation methods, [[rainwater harvesting]] is usually not considered as a form of irrigation. Rainwater harvesting is the collection of runoff water from roofs or unused land and the concentration of this. [71] => [72] => === Treated or untreated wastewater === [73] => [74] => {{excerpt|Reclaimed water#Agricultural reuse}} [75] => [76] => {{excerpt|Reclaimed water#Risks in agricultural reuse}} [77] => [78] => === Other sources === [79] => Irrigation water can also come from non-conventional sources like [[reclaimed water|treated wastewater]],{{cite journal |last1=Moreira da Silva |first1=Manuela |last2=Resende |first2=Flávia C. |last3=Freitas |first3=Bárbara |last4=Aníbal |first4=Jaime |last5=Martins |first5=António |last6=Duarte |first6=Amílcar |title=Urban Wastewater Reuse for Citrus Irrigation in Algarve, Portugal—Environmental Benefits and Carbon Fluxes |journal=Sustainability |date=January 2022 |volume=14 |issue=17 |pages=10715 |doi=10.3390/su141710715|doi-access=free |hdl=10400.1/18203 |hdl-access=free }} [[desalinated water]], [[drainage|drainage water]], or [[fog collection]]. [80] => [81] => In countries where humid air sweeps through at night, water can be obtained by [[condensation]] onto cold surfaces. This is practiced in the vineyards at [[Lanzarote]] using stones to condense water. [[Fog collection|Fog collectors]] are also made of canvas or foil sheets. Using condensate from air conditioning units as a water source is also becoming more popular in large urban areas. [82] => [83] => {{As of|2019|November}} a Glasgow-based startup has helped a farmer in Scotland to establish edible saltmarsh crops irrigated with sea water. An acre of previously marginal land has been put under cultivation to grow [[samphire]], [[Suaeda|sea blite]], and [[Tripolium pannonicum|sea aster]]; these plants yield a higher profit than potatoes. The land is flood irrigated twice a day to simulate tidal flooding; the water is pumped from the sea using wind power. Additional benefits are soil remediation and [[carbon sequestration]].{{cite web |last=McDill |first=Stuart |date=November 27, 2019 |title=Startup helps Scottish farmers grow gourmet plants with sea water |url=https://www.reuters.com/article/us-climate-change-saltwater-farming/startup-helps-scottish-farmers-grow-gourmet-plants-with-sea-water-idUSKBN1Y01V6 |access-date=2 December 2019 |website=Reuters |publisher=Thomson Reuters |quote=Seawater Solutions is helping farmers on Scotland's west coast adapt to the reality of less rain by choosing salt-resistant plants and developing saltmarshes - land flooded by tidal waters - for them to grow in.}}{{cite web |last=O'Toole |first=Emer |date=29 July 2019 |title=Seawater Solutions is tacking agriculture's impact on climate change |url=https://www.thenational.scot/news/17800385.climate-change-scottish-firm-tackling-effects-agriculture/ |access-date=2 December 2019 |website=The National |publisher=Newsquest Media Group Ltd |quote=A system of farming that creates wetland ecosystems on which food can be grown, while carbon is captured at a rate of up to 40 times higher than the same area of rainforest, and profits are more than eight times more profitable than the average potato field.}} [84] => [85] => === Competition for water resources === [86] => {{Main|Water scarcity}} [87] => Until the 1960s, there were fewer than half the number of people on the planet as of 2023. People were not as wealthy as today, consumed fewer calories and [[meat consumption|ate less meat]], so less water was needed to produce their food. They required a third of the volume of water humans presently take from rivers. Today, the competition for [[water resources]] is much more intense, because there are now [[population growth|more than seven billion people]] on the planet, increasing the likelihood of [[overconsumption]] of food produced by water-thirsty animal agriculture and [[intensive farming]] practices. This creates increasing competition for water from [[Industrial sector|industry]], [[urbanisation]] and [[biofuel crops]]. Farmers will have to strive to increase productivity to meet growing [[food security|demands for food]], while industry and cities find ways to use water more efficiently.Chartres, C. and Varma, S. ''Out of water. From Abundance to Scarcity and How to Solve the World's Water Problems'' FT Press (USA), 2010 [88] => [89] => Successful agriculture is dependent upon farmers having sufficient access to water. However, [[water scarcity]] is already a critical constraint to farming in many parts of the world. [90] => [91] => == Irrigation methods == [92] => There are several methods of irrigation. They vary in how the water is supplied to the plants. The goal is to apply the water to the plants as uniformly as possible, so that each plant has the amount of water it needs, neither too much nor too little. Irrigation can also be understood whether it is ''supplementary'' to rainfall as happens in many parts of the world, or whether it is '''full'' irrigation' whereby crops rarely depend on any contribution from rainfall. Full irrigation is less common and only happens in arid landscapes experiencing very low rainfall or when crops are grown in semi-arid areas outside of any rainy seasons. [93] => [94] => ===Surface irrigation=== [95] => {{Main|Surface irrigation}} [96] => [97] => [[File:LevelBasinFloodIrrigation.JPG|thumb|Basin [[flood irrigation]] of [[wheat]]]] [98] => [99] => Surface irrigation, also known as gravity irrigation, is the oldest form of irrigation and has been in use for thousands of years. In ''surface'' (''furrow,'' ''flood'', or ''level basin'') irrigation systems, water moves across the surface of agricultural lands, in order to wet it and infiltrate into the soil. Water moves by following gravity or the slope of the land. Surface irrigation can be subdivided into furrow,'' border strip or basin irrigation''. It is often called ''flood irrigation'' when the irrigation results in flooding or near flooding of the cultivated land. Historically, surface irrigation is the most common method of irrigating agricultural land across most parts of the world. The water application efficiency of surface irrigation is typically lower than other forms of irrigation, due in part to the lack of control of applied depths. Surface irrigation involves a significantly lower capital cost and energy requirement than pressurised irrigation systems. Hence it is often the irrigation choice for developing nations, for low value crops and for large fields. Where water levels from the irrigation source permit, the levels are controlled by dikes ([[levee]]s), usually plugged by soil. This is often seen in terraced rice fields (rice paddies), where the method is used to flood or control the level of water in each distinct field. In some cases, the water is pumped, or lifted by human or animal power to the level of the land. [100] => [[File:Residential flood irrigation in Phoenix, Arizona, in the United States of America.jpg|thumb|Residential flood irrigation in Phoenix, Arizona, US]] [101] => Surface irrigation is even used to water urban gardens in certain areas, for example, in and around [[Phoenix, Arizona]]. The irrigated area is surrounded by a [[berm]] and the water is delivered according to a schedule set by a local [[irrigation district]].{{cite web|title=Flood Irrigation Service|url=http://www.tempe.gov/home/showdocument?id=3194|publisher=City of Tempe, Arizona|access-date=29 July 2017}} [102] => [103] => A special form of irrigation using surface water is [[spate irrigation]], also called floodwater harvesting. In case of a flood (spate), water is diverted to normally dry river beds (wadis) using a network of dams, gates and channels and spread over large areas. The moisture stored in the soil will be used thereafter to grow crops. Spate irrigation areas are in particular located in semi-arid or arid, mountainous regions. [104] => [105] => ===Micro-irrigation=== [106] => {{Main|Micro-irrigation}} [107] => [108] => [[File:Dripperwithdrop.png|thumb|Drip irrigation – a dripper in action]] [109] => ''Micro-irrigation'', sometimes called '''localized irrigation''', '''low volume irrigation''', or '''trickle irrigation''' is a system where water is distributed under low pressure through a piped network, in a pre-determined pattern, and applied as a small discharge to each plant or adjacent to it. Traditional drip irrigation use individual emitters, subsurface drip irrigation (SDI), micro-spray or micro-sprinklers, and mini-bubbler irrigation all belong to this category of irrigation methods.{{cite book | last1 = Frenken | first1 = K. | chapter = Irrigation in Africa in figures – AQUASTAT Survey – 2005 | title = Water Report 29 | publisher = Food and Agriculture Organization of the United Nations | year = 2005 | url = ftp://ftp.fao.org/agl/aglw/docs/wr29_eng.pdf | archive-url = https://web.archive.org/web/20170706015452/ftp://ftp.fao.org/agl/aglw/docs/wr29_eng.pdf | url-status = dead | archive-date = 2017-07-06 | isbn = 978-92-5-105414-7 | access-date = 2007-03-14 }} [110] => [111] => ==== Drip irrigation ==== [112] => [[File:dripirrigation.gif|thumb|Drip irrigation layout and its parts]] [113] => {{Main|Drip irrigation}} [114] => [115] => Drip irrigation, also known as microirrigation or trickle irrigation, functions as its name suggests. In this system, water is delivered at or near the [[root]] zone of plants, one drop at a time. This method can be the most water-efficient method of irrigation,{{cite journal | last = Provenzano | first = Giuseppe | title = Using HYDRUS-2D Simulation Model to Evaluate Wetted Soil Volume in Subsurface Drip Irrigation Systems | journal = Journal of Irrigation and Drainage Engineering| volume = 133 | issue = 4 | pages = 342–350 | year = 2007 | doi = 10.1061/(ASCE)0733-9437(2007)133:4(342)}} if managed properly; evaporation and runoff are minimized. The field [[water efficiency]] of drip irrigation is typically in the range of 80 to 90% when managed correctly. [116] => [117] => In modern agriculture, drip irrigation is often combined with [[plastic mulch]], further reducing evaporation, and is also the means of delivery of fertilizer. The process is known as [[fertigation]]. [118] => [119] => Deep percolation, where water moves below the root zone, can occur if a drip system is operated for too long or if the delivery rate is too high. Drip irrigation methods range from very high-tech and computerized to low-tech and labor-intensive. Lower water pressures are usually needed than for most other types of systems, with the exception of low-energy center pivot systems and surface irrigation systems, and the system can be designed for uniformity throughout a field or for precise water delivery to individual plants in a landscape containing a mix of plant species. Although it is difficult to regulate pressure on steep slopes, pressure compensating [[Drip irrigation#Emitter|emitters]] are available, so the field does not have to be level. High-tech solutions involve precisely calibrated emitters located along lines of tubing that extend from a computerized set of [[valves]].{{Cite web |title=Drip Irrigation System for sustainable agriculture |url=https://www.agriculturelandusa.com/2023/07/Drip-Irrigation-system.html |access-date=2024-03-07 |website=Agriculture land usa}} [120] => [121] => === Sprinkler irrigation === [122] => [[File:Crop sprinklers Rio Vista California 15 Jul 2004-002.jpg|thumb|Crop sprinklers near [[Rio Vista, California]], US]] [123] => [[File:TravellingSprinkler.JPG|thumb|A traveling sprinkler at Millets Farm Centre, [[Oxfordshire]], United Kingdom]] [124] => {{Further|Irrigation sprinkler}} [125] => In ''sprinkler'' or overhead irrigation, water is piped to one or more central locations within the field and distributed by overhead high-pressure sprinklers or guns. A system using sprinklers, sprays, or guns mounted overhead on permanently installed risers is often referred to as a ''solid-set'' irrigation system. Higher pressure sprinklers that rotate are called ''rotors'' and are driven by a ball drive, gear drive, or impact mechanism. Rotors can be designed to rotate in a full or partial circle. Guns are similar to rotors, except that they generally operate at very high pressures of 275 to 900 kPa (40 to 130 psi) and flows of 3 to 76 L/s (50 to 1200 US gal/min), usually with nozzle diameters in the range of 10 to 50 mm (0.5 to 1.9 in). Guns are used not only for irrigation, but also for industrial applications such as dust suppression and [[logging]]. [126] => [127] => Sprinklers can also be mounted on moving platforms connected to the water source by a hose. Automatically moving wheeled systems known as ''traveling sprinklers'' may irrigate areas such as small farms, sports fields, parks, pastures, and cemeteries unattended. Most of these use a length of polyethylene tubing wound on a steel drum. As the tubing is wound on the drum powered by the irrigation water or a small gas engine, the sprinkler is pulled across the field. When the sprinkler arrives back at the reel the system shuts off. This type of system is known to most people as a "waterreel" traveling irrigation sprinkler and they are used extensively for dust suppression, irrigation, and land application of waste water. [128] => [129] => Other travelers use a flat rubber hose that is dragged along behind while the sprinkler platform is pulled by a cable. [130] => [131] => ==== Center pivot ==== [132] => [[File:Center Pivot.jpg|thumb|A small center pivot system from beginning to end]] [133] => [[File:Nelson A3000 Accelerator.png|thumb|Rotator style pivot applicator sprinkler]] [134] => [[File:PivotWithDrops.JPG|thumb|Center pivot with drop sprinklers]] [135] => [[File:WheelLineIrrigation.JPG|thumb|Wheel line irrigation system in [[Idaho]], US, 2001]] [136] => {{Main|Center pivot irrigation}} [137] => [138] => [[File:Crop Triangle South Africa.jpg|alt=Center pivot irrigation|center|thumb|[[Center pivot irrigation]]]] [139] => Center pivot irrigation is a form of sprinkler irrigation utilising several segments of pipe (usually galvanized steel or aluminium) joined and supported by [[truss]]es, mounted on wheeled towers with sprinklers positioned along its length.{{cite web [140] => | url= http://www.thefencepost.com/article/20100525/NEWS/100529954 [141] => | title= Center pivot irrigation revolutionizes agriculture [142] => | work= The Fence Post Magazine [143] => | date= May 25, 2010 [144] => | access-date= June 6, 2012 [145] => | author= Mader, Shelli [146] => | archive-url= https://web.archive.org/web/20160908232107/http://www.thefencepost.com/article/20100525/NEWS/100529954 [147] => | archive-date= September 8, 2016 [148] => | url-status= dead [149] => }} [150] => The system moves in a circular pattern and is fed with water from the pivot point at the center of the arc. These systems are found and used in all parts of the world and allow irrigation of all types of terrain. Newer systems have drop sprinkler heads as shown in the image that follows. [151] => [152] => {{As of | 2017}} most center pivot systems have drops hanging from a U-shaped pipe attached at the top of the pipe with sprinkler heads that are positioned a few feet (at most) above the crop, thus limiting evaporative losses. Drops can also be used with drag hoses or bubblers that deposit the water directly on the ground between crops. Crops are often planted in a circle to conform to the center pivot. This type of system is known as LEPA (Low Energy Precision Application). Originally, most center pivots were water-powered. These were replaced by hydraulic systems (''[[T-L Irrigation]]'') and electric-motor-driven systems (Reinke, Valley, Zimmatic). Many modern pivots feature [[GPS]] devices.{{Cite web|url=https://www.agriculture.com/machinery/irrigation-equipment/gps-swing-arms-prove-their-worth|title=GPS SWING ARMS PROVE THEIR WORTH|last=Gaines|first=Tharran|date=January 7, 2017|website=Successful Farming|access-date=February 1, 2018}} [153] => [154] => ==== Irrigation by lateral move (side roll, wheel line, wheelmove) ==== [155] => [156] => A series of pipes, each with a wheel of about 1.5 m diameter permanently affixed to its midpoint, and sprinklers along its length, are coupled together. Water is supplied at one end using a large hose. After sufficient irrigation has been applied to one strip of the field, the hose is removed, the water drained from the system, and the assembly rolled either by hand or with a purpose-built mechanism, so that the sprinklers are moved to a different position across the field. The hose is reconnected. The process is repeated in a pattern until the whole field has been irrigated. [157] => [158] => This system is less expensive to install than a center pivot, but much more labor-intensive to operate – it does not travel automatically across the field: it applies water in a stationary strip, must be drained, and then rolled to a new strip. Most systems use 100 or 130 mm (4 or 5 inch) diameter aluminum pipe. The pipe doubles both as water transport and as an axle for rotating all the wheels. A drive system (often found near the centre of the wheel line) rotates the clamped-together pipe sections as a single axle, rolling the whole wheel line. Manual adjustment of individual wheel positions may be necessary if the system becomes misaligned. [159] => [160] => Wheel line systems are limited in the amount of water they can carry, and limited in the height of crops that can be irrigated. One useful feature of a lateral move system is that it consists of sections that can be easily disconnected, adapting to field shape as the line is moved. They are most often used for small, rectilinear, or oddly-shaped fields, hilly or mountainous regions, or in regions where labor is inexpensive.{{cite web|last1=Peters|first1=Troy|title=Managing Wheel - Lines and Hand - Lines for High Profitability|url=http://irrigation.wsu.edu/Content/Fact-Sheets/Set-Move-Management.pdf|access-date=29 May 2015|archive-url=https://web.archive.org/web/20161021014252/http://irrigation.wsu.edu/Content/Fact-Sheets/Set-Move-Management.pdf|archive-date=21 October 2016|url-status=dead}}{{cite web|last1=Hill|first1=Robert|title=Wheelmove Sprinkler Irrigation Operation and Management|url=http://extension.usu.edu/files/publications/publication/ENGR_BIE_WM_08.pdf |archive-url=https://ghostarchive.org/archive/20221009/http://extension.usu.edu/files/publications/publication/ENGR_BIE_WM_08.pdf |archive-date=2022-10-09 |url-status=live|access-date=29 May 2015}} [161] => [162] => ==== Lawn sprinkler systems ==== [163] => A lawn sprinkler system is permanently installed, as opposed to a hose-end sprinkler, which is portable. Sprinkler systems are installed in residential lawns, in commercial landscapes, for churches and schools, in public parks and cemeteries, and on [[golf course]]s. Most of the components of these irrigation systems are hidden under ground, since aesthetics are important in a landscape. A typical lawn sprinkler system will consist of one or more zones, limited in size by the capacity of the water source. Each zone will cover a designated portion of the landscape. Sections of the landscape will usually be divided by [[microclimate]], type of plant material, and type of irrigation equipment. A landscape irrigation system may also include zones containing drip irrigation, bubblers, or other types of equipment besides sprinklers. [164] => [165] => Although manual systems are still used, most lawn sprinkler systems may be operated automatically using an [[Controller (irrigation)|irrigation controller]], sometimes called a clock or timer. Most automatic systems employ electric [[solenoid valve]]s. Each zone has one or more of these valves that are wired to the controller. When the controller sends power to the valve, the valve opens, allowing water to flow to the sprinklers in that zone. [166] => [167] => There are two main types of sprinklers used in lawn irrigation, pop-up spray heads and rotors. Spray heads have a fixed spray pattern, while rotors have one or more streams that rotate. Spray heads are used to cover smaller areas, while rotors are used for larger areas. Golf course rotors are sometimes so large that a single sprinkler is combined with a valve and called a 'valve in head'. When used in a turf area, the sprinklers are installed with the top of the head flush with the ground surface. When the system is pressurized, the head will pop up out of the ground and water the desired area until the valve closes and shuts off that zone. Once there is no more pressure in the lateral line, the sprinkler head will retract back into the ground. In flower beds or shrub areas, sprinklers may be mounted on above ground risers or even taller pop-up sprinklers may be used and installed flush as in a lawn area. [168] => [[File:Irrigational sprinkler.jpg|thumb|An [[impact sprinkler]] watering a lawn, an example of a hose-end sprinkler]] [169] => [170] => ==== Hose-end sprinklers ==== [171] => There are many types of hose-end sprinklers. Many of them are smaller versions of larger agricultural and landscape sprinklers, sized to work with a typical garden hose. Some have a spiked base allowing them to be temporarily stuck in the ground, while others have a sled base designed to be dragged while attached to the hose. [172] => [173] => === Subirrigation === [174] => [[Subirrigation]] has been used for many years in field crops in areas with high [[water table]]s. It is a method of artificially raising the water table to allow the [[soil]] to be [[wikt:moisten|moistened]] from below the plants' [[root]] zone. Often those systems are located on permanent grasslands in lowlands or river valleys and combined with drainage infrastructure. A system of pumping stations, canals, weirs and gates allows it to increase or decrease the water level in a network of ditches and thereby control the water table. [175] => [176] => Subirrigation is also used in the [[commerce|commercial]] [[greenhouse]] production, usually for [[potted plant]]s. Water is delivered from below, absorbed by upwards, and the excess collected for recycling. Typically, a solution of water and [[nutrient]]s floods a container or flows through a trough for a short period of time, 10–20 minutes, and is then pumped back into a holding [[Water tank|tank]] for reuse. Sub-irrigation in greenhouses requires fairly sophisticated, expensive equipment and management. Advantages are water and nutrient conservation, and labor savings through reduced system maintenance and [[automation]]. It is similar in principle and action to subsurface basin irrigation. [177] => [178] => Another type of subirrigation is the self-watering container, also known as a [[sub-irrigated planter]]. This consists of a planter suspended over a reservoir with some type of wicking material such as a polyester rope. The water is drawn up the wick through capillary action.{{cite web|url=http://www.entheogen.com/forum/showthread.php?t=13076 |title=Polyester ropes natural irrigation technique |publisher=Entheogen.com |access-date=2012-06-19 |url-status=dead |archive-url=https://web.archive.org/web/20120412031536/http://www.entheogen.com/forum/showthread.php?t=13076 |archive-date=April 12, 2012 }}{{cite web|url=http://www.instructables.com/id/Self-watering-recycled-plant-pot-for-growing-herbs/ |title=DIY instructions for making self-watering system using ropes |publisher=Instructables.com |date=2008-03-17 |access-date=2012-06-19}} A similar technique is the [[wicking bed]]; this too uses capillary action. [179] => [180] => == Efficiency == [181] => Modern irrigation methods are efficient enough to supply the entire field uniformly with water, so that each plant has the amount of water it needs, neither too much nor too little.{{cite web|url=http://agriwaterpedia.info/wiki/Water_use_efficiency|title=Water use efficiency - agriwaterpedia.info}} Water use efficiency in the field can be determined as follows: [182] => * Field Water Efficiency (%) = (Water Transpired by Crop ÷ Water Applied to Field) x 100 [183] => [184] => Increased irrigation efficiency has a number of positive outcomes for the farmer, the community and the wider environment. Low application efficiency infers that the amount of water applied to the field is in excess of the crop or field requirements. Increasing the application efficiency means that the amount of crop produced per unit of water increases. Improved efficiency may either be achieved by applying less water to an existing field or by using water more wisely thereby achieving higher yields in the same area of land. In some parts of the world, farmers are charged for irrigation water hence over-application has a direct financial cost to the farmer. Irrigation often requires pumping energy (either electricity or fossil fuel) to deliver water to the field or supply the correct operating pressure. Hence increased efficiency will reduce both the water cost and energy cost per unit of agricultural production. A reduction of water use on one field may mean that the farmer is able to irrigate a larger area of land, increasing total agricultural production. Low efficiency usually means that excess water is lost through seepage or runoff, both of which can result in loss of crop nutrients or pesticides with potential adverse impacts on the surrounding environment. [185] => [186] => Improving the efficiency of irrigation is usually achieved in one of two ways, either by improving the system design or by optimising the irrigation management. Improving system design includes conversion from one form of irrigation to another (e.g. from furrow to drip irrigation) and also through small changes in the current system (for example changing flowrates and operating pressures). Irrigation management refers to the scheduling of irrigation events and decisions around how much water is applied. [187] => [188] => == Challenges == [189] => [190] => === Environmental impacts === [191] => {{Main|Environmental impact of irrigation}} [192] => [[File:1960- Groundwater loss - depletion - Central Valley of California.svg|thumb |Within a long period of groundwater depletion in California's [[Central Valley (California)|Central Valley]], short periods of recovery have been mostly driven by extreme weather events that typically caused flooding and had negative social, environmental and economic consequences.{{cite journal |last1=Liu |first1=Pang-Wei |last2=Famiglietti |first2=James S. |last3=Purdy |first3=Adam J. |last4=Adams |first4=Kyra H. |last5=McEvoy |first5=Avery L. |last6=Reager |first6=John T. |last7=Bindlish |first7=Rajat |last8=Wiese |first8=David N. |last9=David |first9=Cédric H. |last10=Rodell |first10=Matthew |display-authors=4 |title=Groundwater depletion in California's Central Valley accelerates during megadrought |journal=Nature Communications |date=19 December 2022 |volume=13 |issue=7825 |page=7825 |doi=10.1038/s41467-022-35582-x |doi-access=free |pmid=36535940 |pmc=9763392 |bibcode=2022NatCo..13.7825L }} ([https://web.archive.org/web/20230130223801/https://www.nature.com/articles/s41467-022-35582-x/figures/4 Archive] of chart itself)]] [193] => Negative impacts frequently accompany extensive irrigation. Some projects which diverted surface water for irrigation dried up the water sources, which led to a more extreme regional climate.[[#refMcNeill2000|McNeill 2000]] pp.164-165. Projects that relied on groundwater and pumped too much from underground aquifers created [[groundwater-related subsidence|subsidence]] and [[freshwater salinization|salinization]]. Salinization of irrigation water in turn damaged the crops and seeped into drinking water. Pests and pathogens also thrived in the irrigation canals or ponds full of still water, which created regional outbreaks of diseases like [[malaria]] and [[schistosomiasis]].[[#refJohnson2019|McNeill 200]].[[#refWorster1992|McNeill 200]] pp.112-13.[[#refMcNeill2000|McNeill 200]] pp.171. Governments also used irrigation schemes to encourage migration, especially of more desirable populations into an area.[[#refParker2020|Parker 2020]][[#refVisser2018|Visser 2018]][[#refWorster1992|Worster 1992]] pp.156-57. Additionally, some of these large nationwide schemes failed to pay off at all, costing more than any benefit gained from increased crop yields.[[#refPisani2002|Pisani 2002]] p.5.[[#refMcNeill2000|McNeill 2000]] [194] => [195] => [[Overdrafting]] (depletion) of underground [[aquifers]]: In the mid-20th century, the advent of diesel and electric motors led to systems that could pump [[groundwater]] out of major [[aquifer]]s faster than [[drainage basin]]s could refill them. This can lead to permanent loss of aquifer capacity, decreased water quality, ground subsidence, and other problems. The future of food production in such areas as the [[North China Plain]], the [[Punjab region]] in India and Pakistan, and the [[Great Plains]] of the US is threatened by this phenomenon.{{cite news |date=2013-06-22 |title=A new report says we're draining our aquifers faster than ever |newspaper=High Country News |url=https://www.hcn.org/issues/45.12/a-new-report-says-were-draining-our-aquifers-faster-than-ever |access-date=2014-02-11}}{{cite web |title=Management of aquifer recharge and discharge processes and aquifer storage equilibrium |url=http://www.groundwatergovernance.org/fileadmin/user_upload/groundwatergovernance/docs/Thematic_papers/GWG_Thematic_Paper_4.pdf |url-status=dead |archive-url=https://web.archive.org/web/20180921042755/http://www.groundwatergovernance.org/fileadmin/user_upload/groundwatergovernance/docs/Thematic_papers/GWG_Thematic_Paper_4.pdf |archive-date=2018-09-21 |access-date=2014-02-11}} [196] => [197] => {{excerpt|Environmental effects of irrigation|file=no}} [198] => [199] => === Technical challenges === [200] => [[File:Сток воды при орошении.png|thumb|Overirrigation because of poor distribution uniformity in the furrows. Potato plants were oppressed and turned yellow]] [201] => Irrigation schemes involve solving numerous engineering and economic problems while minimizing negative environmental consequences.ILRI, 1989, Effectiveness and Social/Environmental Impacts of Irrigation Projects: a Review. In: Annual Report 1988, International Institute for Land Reclamation and Improvement (ILRI), Wageningen, The Netherlands, pp. 18 – 34 . On line: [http://www.waterlog.info/pdf/irreff.pdf] Such problems include: [202] => * Ground [[subsidence]] (e.g. [[New Orleans, Louisiana]]) [203] => * Underirrigation or irrigation giving only just enough water for the plant (e.g. in drip line irrigation) gives poor [[soil salinity control]] which leads to increased [[soil salinity]] with consequent buildup of toxic salts on soil surface in areas with high evaporation. This requires either [[leaching (agriculture)|leaching]] to remove these salts and a method of [[drainage]] to carry the salts away. When using drip lines, the leaching is best done regularly at certain intervals (with only a slight excess of water), so that the salt is flushed back under the plant's roots.EOS magazine, September 2009 [204] => * [[wikt:Overirrigation|Overirrigation]] because of poor [[distribution uniformity]] or [[irrigation scheduling|management]] wastes water, chemicals, and may lead to [[water pollution]].Hukkinen, Janne, Emery Roe, and Gene I. Rochlin. "A salt on the land: A narrative analysis of the controversy over irrigation-related salinity and toxicity in California's San Joaquin Valley." ''Policy Sciences'' 23.4 (1990): 307–329. [http://blogs.helsinki.fi/jahukkin/files/2012/02/PolSci1990.pdf online] {{webarchive|url=https://web.archive.org/web/20150102191753/http://blogs.helsinki.fi/jahukkin/files/2012/02/PolSci1990.pdf |date=2015-01-02 }} [205] => * Deep drainage (from over-irrigation) may result in rising water tables which in some instances will lead to problems of irrigation [[Soil salinity|salinity]] requiring [[watertable control]] by some form of [[Drainage system (agriculture)|subsurface land drainage]].{{cite book | title = Drainage Manual: A Guide to Integrating Plant, Soil, and Water Relationships for Drainage of Irrigated Lands | year = 1993 | publisher = Interior Dept., Bureau of Reclamation | isbn = 978-0-16-061623-5 }}{{cite web |url=http://www.waterlog.info |title=Free articles and software on drainage of waterlogged land and soil salinity control in irrigated land |access-date=2010-07-28 }} For example in [[Australia]], over-abstraction of fresh water for intensive irrigation activities has caused 33% of the land area to be at risk of [[Soil salinity|salination]].{{cite journal |author=Gordon L., D. M. |year=2003 |title=Land cover change and water vapour flows: learning from Australia |journal=Philosophical Transactions of the Royal Society B: Biological Sciences |volume=358 |issue=1440 |pages=1973–1984 |doi=10.1098/rstb.2003.1381 |jstor=3558315 |pmc=1693281 |pmid=14728792}} [206] => * [[Saffman–Taylor instability|Drainage front instability]], also known as viscous fingering, where an unstable drainage front results in a pattern of fingers and viscous entrapped saturated zones. [207] => * Irrigation with [[saline water|saline]] or [[sodium adsorption ratio|high-sodium]] water may damage soil structure owing to the formation of [[alkaline soil]]. [208] => * Clogging of filters: algae can clog filters, drip installations, and nozzles. Chlorination, algaecide, UV and ultrasonic methods can be used for algae control in irrigation systems. [209] => * Complications in accurately measuring irrigation performance which changes over time and space using measures such as productivity, efficiency, equity and adequacy.{{Cite journal|date=2020-11-01|title=A scale-based framework to understand the promises, pitfalls and paradoxes of irrigation efficiency to meet major water challenges|journal=Global Environmental Change|language=en|volume=65|pages=102182|doi=10.1016/j.gloenvcha.2020.102182|issn=0959-3780|doi-access=free|last1=Lankford|first1=Bruce|last2=Closas|first2=Alvar|last3=Dalton|first3=James|last4=López Gunn|first4=Elena|last5=Hess|first5=Tim|last6=Knox|first6=Jerry W.|last7=Van Der Kooij|first7=Saskia|last8=Lautze|first8=Jonathan|last9=Molden|first9=David|last10=Orr|first10=Stuart|last11=Pittock|first11=Jamie|last12=Richter|first12=Brian|last13=Riddell|first13=Philip J.|last14=Scott|first14=Christopher A.|last15=Venot|first15=Jean-Philippe|last16=Vos|first16=Jeroen|last17=Zwarteveen|first17=Margreet|hdl=1885/224453|hdl-access=free}} [210] => * Macro-irrigation, typical in [[intensive agriculture]], where also are used agrochemicals, often causes [[eutrophication]]. [211] => [212] => === Social aspects === [213] => * Competition for surface [[water right]]sRosegrant, Mark W., and Hans P. Binswanger. "Markets in tradable water rights: potential for efficiency gains in developing country water resource allocation." ''World development'' (1994) 22#11 pp: 1613–1625. and [[territory defense]]. [214] => * Assisting smallholders in sustainably and collectively managing irrigation technology and changes in technology.{{Cite book |last=Venot |first=Jean-Philippe |title=Drip Irrigation for Agriculture |date=2017-07-06 |isbn=9781315537146 |editor1-last=Venot |editor1-first=Jean-Philippe |doi=10.4324/9781315537146 |editor2-last=Kuper |editor2-first=Marcel |editor3-last=Zwarteveen |editor3-first=Margreet}} [215] => [216] => == History == [217] => [218] => === Ancient history === [219] => [[File:David Roberts ancient fountain.jpg|thumb|upright|Animal-powered irrigation, Upper Egypt, ca. 1846]] [220] => [221] => Archaeological investigation has found evidence of irrigation in areas lacking sufficient natural [[rainfall]] to support crops for [[rainfed agriculture]]. Some of the earliest known use of the technology dates to the 6th millennium BC in [[Khuzestan Province|Khuzistan]] in the south-west of [[Iran]].{{cite book |last1=Flannery |first1=Kent V. |title=The Domestication and Exploitation of Plants and Animals |publisher=Transaction Publishers |year=1969 |isbn=9780202365572 |editor1-last=Ucko |editor1-first=Peter John |editor1-link=Peter John Ucko |location=New Brunswick, New Jersey |publication-date=2007 |page=89 |chapter=Origins and ecological effects of early domestication in Iran and the Near East |author-link1=Kent V. Flannery |access-date=2019-01-12 |editor2-last=Dimbleby |editor2-first=G. W. |chapter-url=https://books.google.com/books?id=6lY9Q4vnrCEC}} [222] => {{cite book |last1=Lawton |first1=H. W. |title=Agriculture in Semi-Arid Environments |last2=Wilke |first2=P. J. |publisher=Springer Science & Business Media |year=1979 |isbn=9783642673283 |editor1-last=Hall |editor1-first=A. E. |edition=reprint |series=Ecological Studies |volume=34 |location=Berlin |publication-date=2012 |page=13 |chapter=Ancient Agricultural Systems in Dry Regions of the Old World |access-date=2019-01-12 |editor2-last=Cannell |editor2-first=G. H. |editor3-last=Lawton |editor3-first=H.W. |chapter-url=https://books.google.com/books?id=e67tCAAAQBAJ}} [223] => The site of [[Choga Mami]], in present-day Iraq on the border with Iran, is believed to be the earliest to show the first canal irrigation in operation at about 6000 BCE.Alexander R. Thomas, Gregory M. Fulkerson (2021), [https://books.google.com/books?id=KcUyEAAAQBAJ&pg=PA137 City and Country: The Historical Evolution of Urban-Rural Systems.] Rowman & Littlefield. p.137 [224] => [225] => Irrigation was used as a means of manipulation of water in the alluvial plains of the [[Indus valley civilization]], the application of which is estimated to have begun around 4500 BC and drastically increased the size and prosperity of their agricultural settlements.{{cite book |url=https://books.google.com/books?id=JI65-MygMm0C |title=The Basis of Civilization--water Science? |date=2004 |publisher=International Association of Hydrological Science |isbn=9781901502572 |editor1-last=Rodda |editor1-first=J. C. |language=en |editor2-last=Ubertini |editor2-first=Lucio}} The Indus Valley Civilization developed sophisticated irrigation and water-storage systems, including artificial [[reservoir]]s at [[Girnar]] dated to 3000 BCE, and an early [[canal]] irrigation system from {{circa}} 2600 BCE. Large-scale agriculture was practiced, with an extensive network of canals used for the purpose of irrigation.{{cite web |title=Ancient India Indus Valley Civilization |url=http://www.mnsu.edu/emuseum/prehistory/india/indus/elements.html |url-status=dead |archive-url=https://web.archive.org/web/20070205113936/http://www.mnsu.edu/emuseum/prehistory/india/indus/elements.html |archive-date=2007-02-05 |access-date=2007-01-10 |publisher=Minnesota State University "e-museum"}} [226] => [227] => Farmers in the [[Mesopotamia]]n plain used irrigation from at least the third millennium BCE. [228] => {{cite book |url=https://books.google.com/books?id=4SKYAAAAQBAJ |title=The Sumerian World |publisher=Routledge |year=2013 |isbn=9781136219115 |editor1-last=Crawford |editor1-first=Harriet |editor-link=Harriet Crawford |series=Routledge Worlds |location=Abingdon, Oxfordshire |publication-date=2013 |access-date=2019-01-12}} [229] => [230] => They developed ''perennial irrigation'', regularly watering crops throughout the [[growing season]] by coaxing water through a [[Matrix (mathematics)|matrix]] of small channels formed in the field. [231] => {{cite book |last1=Hill |first1=Donald |title=A History of Engineering in Classical and Medieval Times |publisher=Routledge |year=1984 |isbn=9781317761570 |edition=reprint |location=London |publication-date=2013 |page=18 |chapter=2: Irrigation and Water supply |author-link1=Donald Hill |access-date=2019-01-12 |chapter-url=https://books.google.com/books?id=oMceAgAAQBAJ}} [232] => [233] => [[Ancient Egyptians]] practiced ''basin irrigation'' using the [[flooding of the Nile]] to inundate land plots which had been surrounded by [[Levee|dikes]]. The flood water remained until the fertile sediment had settled before the engineers returned the surplus to the [[watercourse]].''p19'' Hill There is evidence of the ancient Egyptian [[pharaoh]] [[Amenemhet III]] in the [[Twelfth dynasty of Egypt|twelfth dynasty]] (about 1800 [[Common era|BCE]]) using the natural lake of the [[Faiyum Oasis]] as a reservoir to store surpluses of water for use during dry seasons. The lake swelled annually from the flooding of the [[Nile]].{{cite web |title=Amenemhet III |url=http://concise.britannica.com/ebc/article-9006076/Amenemhet-III |url-status=dead |archive-url=https://web.archive.org/web/20070510203748/http://concise.britannica.com/ebc/article-9006076/Amenemhet-III |archive-date=2007-05-10 |access-date=2007-01-10 |publisher=Britannica Concise}} [234] => [[File:Scene at Bhimgoda near Haridwar , February 1847.jpg|thumb|Young [[engineer]]s restoring and developing the old [[Mughal Empire|Mughal]] irrigation system in 1847 during the reign of the [[Mughal Emperor]] [[Bahadur Shah II]] in Indian subcontinent]] [235] => The [[Nubia|Ancient Nubians]] developed a form of irrigation by using a [[waterwheel]]-like device called a ''[[sakia]]''. Irrigation began in Nubia some time between the third and second millennia BCE.{{cite book |author=G. Mokhtar |url=https://books.google.com/books?id=gB6DcMU94GUC&q=ancient+irrigation+Africa&pg=PA309 |title=Ancient civilizations of Africa |date=1981-01-01 |publisher=Unesco. International Scientific Committee for the Drafting of a General History of Africa |isbn=9780435948054 |page=309 |access-date=2012-06-19 |via=Books.google.com}} It largely depended upon the flood waters that would flow through the [[Nile River]] and other rivers in what is now the Sudan.{{cite book |last1=Bulliet |first1=Richard |url=https://books.google.com/books?id=niqhizFDhKUC&q=irrigation+Nubia+BCE&pg=PA53 |title=The Earth and Its Peoples, Volume I: A Global History, to 1550 |last2=Crossley |first2=Pamela Kyle |last3=Headrick |first3=Daniel |last4=Hirsch |first4=Steven |date=2008-06-18 |isbn=978-0618992386 |pages=53–56|publisher=Wadsworth }} [236] => [237] => In [[sub-Saharan Africa]] irrigation reached the [[Niger River]] region cultures and civilizations by the first or second millennium BCE and was based on wet-season flooding and water harvesting.{{cite web |title=Traditional technologies |url=http://www.fao.org/docrep/004/y0969e/y0969e03.htm |access-date=2012-06-19 |publisher=Fao.org}}{{cite web |title=Africa, Emerging Civilizations In Sub-Sahara Africa. Various Authors; Edited By: R. A. Guisepi |url=http://history-world.org/africa.htm |url-status=usurped |archive-url=https://web.archive.org/web/20100612221652/http://history-world.org/africa.htm |archive-date=2010-06-12 |access-date=2012-06-19 |publisher=History-world.org}} [238] => [239] => Evidence of ''terrace irrigation'' occurs in pre-Columbian America, early Syria, India, and China. In the Zana Valley of the [[Andes Mountains]] in [[Peru]], archaeologists have found remains of three irrigation [[canal]]s [[Radiocarbon dating|radiocarbon-dated]] from the [[4th millennium BCE]], the 3rd millennium BCE and the 9th century [[Common era|CE]]. These canals provide the earliest record of irrigation in the [[New World]]. Traces of a canal possibly dating from the [[5th millennium BCE]] were found under the 4th-millennium canal. [240] => [241] => [[Ancient Persia]] (modern day [[Iran]]) used irrigation as far back as the [[6th millennium BCE]] to grow barley in areas with insufficient natural rainfall.{{cite book |title=The History of Technology – Irrigation |publisher=Encyclopædia Britannica, 1994 edition}} The [[Qanat]]s, developed in ancient [[Persia]] about 800 BCE, are among the oldest known irrigation methods still in use today. They are now found in Asia, the Middle East and North Africa. The system comprises a network of vertical wells and gently sloping tunnels driven into the sides of cliffs and of steep hills to tap groundwater.{{cite web |title=Qanat Irrigation Systems and Homegardens (Iran) |url=http://www.fao.org/sd/giahs/other_iran1_desc.asp |access-date=2007-01-10 |work=Globally Important Agriculture Heritage Systems |publisher=UN Food and Agriculture Organization |archive-date=June 24, 2008 |archive-url=https://web.archive.org/web/20080624023533/http://www.fao.org/sd/giahs/other_iran1_desc.asp |url-status=dead }} The [[noria]], a water wheel with clay pots around the rim powered by the flow of the stream (or by animals where the water source was still), first came into use at about this time among [[Roman Republic|Roman]] settlers in North Africa. By 150 BCE the pots were fitted with valves to allow smoother filling as they were forced into the water.''Encyclopædia Britannica'', 1911 and 1989 editions [242] => [243] => ====Sri Lanka==== [244] => {{Main|Sri Lankan irrigation network}} [245] => [246] => The irrigation works of ancient [[Sri Lanka]], the earliest dating from about 300 BCE in the reign of King [[Pandukabhaya]], and under continuous development for the next thousand years, were one of the most complex irrigation systems of the ancient world. In addition to underground canals, the [[Sinhalese people|Sinhalese]] were the first to build completely artificial reservoirs to store water.{{citation needed|date=January 2019}} These reservoirs and canal systems were used primarily to irrigate [[paddy field]]s, which require a lot of water to cultivate. Most of these irrigation systems still exist undamaged up to now, in [[Anuradhapura]] and [[Polonnaruwa]], because of the advanced and precise engineering. The system was extensively restored and further extended during the reign of King [[Parakrama Bahu]] (1153–1186 [[Common era|CE]]).{{cite web |last=de Silva |first=Sena |year=1998 |title=Reservoirs of Sri Lanka and their fisheries |url=http://www.fao.org/docrep/003/T0028E/T0028E03.htm |access-date=2007-01-10 |publisher=UN Food and Agriculture Organization}} [247] => [248] => ==== China ==== [249] => [[File:Turpan-karez-museo-d02.jpg|thumb|Inside a [[Turfan water system|karez]] tunnel at [[Turpan]], Xinjiang, China]] [250] => The oldest known [[hydraulic]] engineers of [[China]] were [[Sunshu Ao]] (6th century BCE) of the [[Spring and Autumn period]] and [[Ximen Bao]] (5th century BCE) of the [[Warring States]] period, both of whom worked on large irrigation [[project]]s. In the [[Sichuan]] region belonging to the [[Qin (state)|state of Qin]] of ancient China, the [[Dujiangyan Irrigation System]] devised by the Qin Chinese hydrologist and irrigation engineer [[Li Bing (Qin)|Li Bing]] was built in 256 BCE to irrigate a vast area of farmland that today still supplies water.{{cite book |title=China – history |publisher=Encyclopædia Britannica,1994 edition}} By the 2nd century AD, during the [[Han Dynasty]], the Chinese also used [[chain pump]]s which lifted water from a lower elevation to a higher one.Needham, Joseph (1986). ''Science and Civilization in China: Volume 4, Physics and Physical Technology, Part 2, Mechanical Engineering''. Taipei: Caves Books Ltd. Pages 344–346. These were powered by manual foot-pedal, hydraulic [[waterwheel]]s, or rotating mechanical wheels pulled by [[oxen]].Needham, Volume 4, Part 2, 340–343. The water was used for [[public works]], providing water for urban residential quarters and palace gardens, but mostly for irrigation of [[arable land|farmland]] canals and channels in the fields.Needham, Volume 4, Part 2, 33, 110. [251] => [252] => ==== Korea ==== [253] => [[Joseon|Korea]], [[Jang Yeong-sil]], a Korean engineer of the [[Joseon Dynasty]], under the active direction of the king, [[Sejong the Great]], invented the world's first rain-gauge, ''uryanggye'' ({{Korean|hangul=우량계}}) in 1441. It was installed in irrigation tanks as part of a nationwide system to measure and collect rainfall for agricultural applications. With this instrument, planners and farmers could make better use of the information gathered in the{{which|date=January 2019}} survey.{{cite book |last=Baek Seok-gi 백석기 |title=Jang Yeong-sil 장영실 |publisher=Woongjin Wiin Jeon-gi 웅진위인전기 11. Woongjin Publishing Co., Ltd |year=1987}} [254] => [255] => ==== North America ==== [256] => {{Main|Hohokam}} [257] => [258] => The earliest agricultural irrigation canal system known in the area of the present-day [[United States of America|United States]] dates to between 1200 B.C. and 800 B.C. and was discovered by Desert Archaeology, Inc. in Marana, Arizona (adjacent to Tucson) in 2009.{{cite web |title=Earliest Canals in America – Archaeology Magazine Archive |url=http://archive.archaeology.org/0909/trenches/canals.html}} The irrigation-canal system predates the Hohokam culture by two thousand years and belongs to an unidentified culture. In North America, the Hohokam were the only culture known to rely on irrigation canals to water their crops, and their irrigation systems supported the largest population in the Southwest by AD 1300. The Hohokam constructed an assortment of simple canals combined with [[weirs]] in their various agricultural pursuits. Between the 7th and 14th centuries they built and maintained extensive irrigation networks along the lower [[Salt River (Arizona)|Salt]] and middle [[Gila River]]s that rivaled the complexity of those used in the ancient Near East, Egypt, and China. These were constructed using relatively simple excavation tools, without the benefit of advanced engineering technologies, and achieved drops of a few feet per mile, balancing erosion and siltation. The Hohokam cultivated varieties of cotton, tobacco, maize, beans and squash, as well as harvesting an assortment of wild plants. Late in the Hohokam Chronological Sequence, they also used extensive dry-farming systems, primarily to grow [[Agave murpheyi|agave]] for food and fiber. Their reliance on agricultural strategies based on canal irrigation, vital in their less-than-hospitable desert environment and arid climate, provided the basis for the aggregation of rural populations into stable urban centers. [259] => James M. Bayman, "The Hohokam of Southwest North America." ''Journal of World Prehistory'' 15.3 (2001): 257–311. [260] => [261] => [262] => ====South America==== [263] => {{see also|Zaña Valley}} [264] => [265] => The oldest known irrigation canals in the Americas are in the desert of northern Peru in the Zaña valley near the hamlet of [[Nanchoc District|Nanchoc]]. The canals have been [[radiocarbon]] dated to at least 3400 B.C. and possibly as old as 4700 B.C. The canals at that time irrigated crops such as [[peanut]]s, [[Cucurbita|squash]], [[manioc]], [[chenopodium|chenopods]], a relative of [[Quinoa]], and later [[maize]].{{cite journal |last1=Dillehay |first1=Tom D. |last2=Eling |first2=Herbert H. Jr. |last3=Rossen |first3=Jack |year=2005 |title=Preceramic irrigation canals in the Peruvian Andes |url=https://www.pnas.org/content/pnas/102/47/17241.full.pdf |url-status=live |journal=Proceedings of the National Academy of Sciences of the United States of America |publisher=National Academy of Science |volume=102 |issue=47 |pages=17241–17244 |bibcode=2005PNAS..10217241D |doi=10.1073/pnas.0508583102 |pmc=1288011 |pmid=16284247 |archive-url=https://ghostarchive.org/archive/20221009/https://www.pnas.org/content/pnas/102/47/17241.full.pdf |archive-date=2022-10-09 |access-date=20 November 2020 |doi-access=free}} [266] => [267] => ===Modern history=== [268] => The scale of irrigation increased dramatically over the 20th century. In 1800, 8 million hectares globally were irrigated, in 1950, 94 million hectares, and in 1990, 235 million hectares. By 1990, 30% of the global food production came from irrigated land. Irrigation techniques across the globe included canals redirecting surface water, groundwater pumping, and diverting water from dams. National governments led most irrigation schemes within their borders, but private investors and other nations, especially the [[United States]], [[China]], and European countries like the [[United Kingdom]], funded and organized some schemes within other nations. Irrigation enabled the production of more crops, especially [[cash crop|commodity crops]] in areas which otherwise could not support them. Countries frequently invested in irrigation to increase [[wheat]], [[rice]], or [[cotton]] production, often with the overarching goal of increasing self-sufficiency. In the 20th century, global anxiety specifically about the American cotton monopoly fueled many empirical irrigation projects: Britain began developing irrigation in [[India]], the [[Ottoman Empire|Ottomans]] in [[Egypt]], the [[France|French]] in [[Algeria]], the [[Portugal|Portuguese]] in [[Angola]], the [[Germany|Germans]] in [[Togo]], and [[Soviet Union|Soviets]] in [[Central Asia]]. [269] => [270] => Negative impacts frequently accompanied extensive irrigation. Some projects which diverted surface water for irrigation dried up the water sources, which led to a more extreme regional climate. Projects that relied on groundwater and pumped too much from underground aquifers created [[groundwater-related subsidence|subsidence]] and [[freshwater salinization|salinization]]. Salinization of irrigation water in turn damaged the crops and seeped into drinking water. Pests and pathogens also thrived in the irrigation canals or ponds full of still water, which created regional outbreaks of diseases like [[malaria]] and [[schistosomiasis]]. Governments also used irrigation schemes to encourage migration, especially of more desirable populations into an area. Additionally, some of these large nationwide schemes failed to pay off at all, costing more than any benefit gained from increased crop yields. [271] => [272] => ====American West==== [273] => Irrigated land in the [[United States]] increased from 300,000 acres in 1880 to 4.1 million in 1890, then to 7.3 million in 1900. Two thirds of this irrigation sources from [[groundwater]] or small ponds and [[reservoirs]], while the other one third comes from large [[dam]]s.[[#refMcCully2001|McCully 2001]] p. 166. One of the main attractions of irrigation in the West was its increased dependability compared to rainfall-watered agriculture in the East. Proponents argued that farmers with a dependable water supply could more easily get loans from bankers interested in this more predictable farming model.[[#refWorster1992|Worster 1992]] pp.114-15. Most irrigation in the [[Great Plains]] region derived from underground [[aquifer]]s. Euro-American farmers who colonized the region in the 19th century tried to grow the commodity crops that they were used to, like [[wheat]], [[maize|corn]], and [[alfalfa]], but rainfall stifled their growing capacity. Between the late 1800s and the 1930s, farmers used [[windpump|wind-powered pumps]] to draw groundwater. These windpumps had limited power, but the development of gas-powered pumps in the mid-1930s pushed wells deep into the [[Ogallala Aquifer]]. Farmers irrigated fields by laying pipes across the field with [[irrigation sprinkler|sprinklers]] at intervals, a labor-intensive process, until the advent of the [[center pivot irrigation|center-pivot sprinkler]] after WWII, which made irrigation significantly easier.{{Citation |title=How Center Pivot Irrigation Brought the Dust Bowl Back to Life |url=https://www.smithsonianmag.com/innovation/how-center-pivot-irrigation-brought-dust-bowl-back-to-life-180970243/ |access-date=6 May 2022}} By the 1970s farmers drained the aquifer ten times faster than it could recharge, and by 1993 they had removed half of the accessible water.[[#refMcNeill2000|McNeill 2000]] pp. 151-52 [274] => [275] => Large-scale federal funding and intervention pushed through the majority of irrigation projects in the West, especially in [[California]], [[Colorado]], [[Arizona]], and [[Nevada]]. At first, plans to increase irrigated farmland, largely by giving land to farmers and asking them to find water, failed across the board. Congress passed the [[Desert Land Act]] in 1877 and the [[Carey Act]] in 1894, which only marginally increased irrigation.[[#refWorster1992|Worster 1992]] pp.156-157. Only in 1902 Congress passed the [[Newlands Reclamation Act|National Reclamation Act]], which channeled money from the sale of western public lands, in parcels up to 160 acres large, into irrigation projects on public or private land in the arid West.[[#refWorster1992|Worster 1992]] p. 161. The Congressmen who passed the law, as well as their wealthy supporters, supported Western irrigation because it would increase American exports, ‘reclaim’ the West, and push the Eastern poor out West in search of a better life.[[#refWorster1992|Worster 1992]] pp.166-67. [276] => [277] => While the National Reclamation Act was the most successful piece of federal irrigation legislation, the implementation of the act did not go as planned. Originally, the [[United States Bureau of Reclamation|Reclamation Service]] planned to construct a small number of projects that would allow engineers to learn from the process, but [[Theodore Roosevelt|President Roosevelt]] chose instead push as many irrigation projects through as fast as possible. The Reclamation Service also chose to push most of the Act's money toward construction rather than settlement, so the Service overwhelmingly prioritized building large dams like the [[Hoover Dam]].[[#refPisani2002|Pisani 2002]] p.30. Over the 20th century Congress and state governments grew more frustrated with the Reclamation Service and the irrigation schemes in general. [[Frederick Haynes Newell|Frederick Newell]], head of the Reclamation Service, proving uncompromising and difficult to work with, falling crop prices, resistance to delay debt payments, and refusal to begin new projects until the completion of old ones all contributed.[[#refPisani2002|Pisani 2002]] p.152. The [[Reclamation Extension Act of 1914]], transferring a significant amount of irrigation decision-making power regarding irrigation projects from the Reclamation Service to Congress, was in many ways a result of an increasing political unpopularity of the Reclamation Service.[[#refPisani2002|Pisani 2002]]. [278] => [279] => In the lower [[Colorado River|Colorado Basin]] of [[Arizona]], [[Colorado]], and [[Nevada]], the states derive irrigation water largely from rivers, especially the [[Colorado River]], which irrigates more than 4.5 million acres of land, with a less significant amount coming from groundwater.{{Citation |title=Colorado River Basin Studies |url=https://www.usgs.gov/centers/utah-water-science-center/science/colorado-river-basin-studies |access-date=6 May 2022}} In the 1952 case [[Arizona v. California]], Arizona sued California for increased access to the Colorado, under the grounds that their groundwater supply could not sustain their almost entirely irrigation-based agricultural economy, which they won.{{cite book |url=http://site.ebrary.com/lib/yale/Doc?id=10631172 |title=Dividing western waters: Mark Wilmer and Arizona v. California |vauthors=((August, J. L.)) |date=2007 |publisher=TCU Press}} California, which began irrigating in earnest in the 1870s in [[San Joaquin Valley]],[[#refWorster1992|Worster 1992]] p. 102. had passed the [[Wright Act of 1887]] permitting agricultural communities to construct and operate needed irrigation works.[[#refWorster1992|Worster 1992]] p. 108. The Colorado also irrigates large fields in California's [[Imperial Valley]], fed by the National Reclamation Act-built All-American Canal.[[#refMcNeill2000|McNeill 2000]] p. 178[[#refWorster1992|Worster 1992]] p.208. [280] => [281] => ====Soviet Central Asia==== [282] => When the [[Bolsheviks]] conquered [[Soviet Central Asia|Central Asia]] in 1917, the native [[Kazakhs]], [[Uzbeks]], and [[Turkmens]] used minimal irrigation. The Slavic immigrants pushed into the area by the Tsarist government{{Citation |title=Slavic peasant settlers in Russian Turkestan, 1886-1917 |url=https://www.google.com/search?q=Slavic+peasant+settlers+in+Russian+Turkestan%2C+1886-1917+morrison |access-date=6 May 2022 |vauthors=((Morrison, A.))}} brought their own irrigation methods, including waterwheels, the use of [[paddy fields|rice paddies]] to restore salted land, and underground irrigation channels. Russians dismissed these techniques as crude and inefficient. Despite this, in absence of other solutions, tsarist officials maintained these systems through the late 19th century.[[#refPeterson2016|Peterson 2016]]. [283] => [284] => Before conquering the area, the Russian government accepted a 1911 American proposal to send hydraulic experts to Central Asia to investigate the potential for large-scale irrigation. A 1918 decree by [[Lenin]] then encouraged irrigation development in the region, and development began in the 1930s. When it did, [[Joseph Stalin|Stalin]] and other Soviet leaders prioritized large-scale, ambitious hydraulic projects, especially along the [[Volga|Volga River]]. The Soviet irrigation push stemmed largely from their late 19th century fears of the American cotton monopoly and subsequent desire to achieve cotton self-sufficiency.[[#refMcNeill2000|McNeill 2000]] p. 163 They had built up their textile manufacturing industry in the 19th century, requiring increased cotton and irrigation, as the region did not receive enough rainfall to support cotton farming. [285] => [286] => The Russians built dams on the [[Don (river)|Don]] and [[Kuban (river)|Kuban]] Rivers for irrigation, removing freshwater flow from the [[Sea of Azov]] and making it much saltier. Depletion and salinization scourged other areas of the Russian irrigation project. In the 1950s Soviet officials began also diverting the [[Syr Darya]] and the [[Amu Darya]], which fed the [[Aral Sea]]. Before diversion, the rivers delivered 55km3 of water to the Aral Sea per year, but after they only delivered 6km3 to the Sea. Because of its reduced inflow, the Aral Sea covered less than half of its original seabed, which made the regional climate more extreme and created airborne salinization, lowering nearby crop yields.[[#refMcNeill2000|McNeill 2000]] pp. 164-5 [287] => [288] => By 1975, the USSR used eight times as much water as they had in 1913, mostly for irrigation. Russia's expansion of irrigation began to decrease in the late 1980s, and irrigated hectares in Central Asia capped out at 7 million. [[Mikhail Gorbachev]] killed a proposed plan to reverse the Ob and Yenisei for irrigation in 1986, and the breakup of the USSR in 1991 ended Russian investment in Central Asian cotton irrigation.[[#refMcNeill2000|McNeill 2000]] p. 166 [289] => [290] => ====Africa==== [291] => Different irrigation schemes with a variety of goals and success rates have been implemented across Africa in the 20th century, but have all been influenced by colonial forces. The [[Tana River (Kenya)|Tana River]] Irrigation Scheme in eastern [[Kenya]], completed between 1948 and 1963, opened up new lands for agriculture, and the Kenyan government attempted to resettle the area with detainees from the [[Mau Mau rebellion|Mau Mau uprising]].[[#refParker2020|Parker 2020]]. Libya's underground water resources were discovered by Italian oil drillers during the [[Italian colonization of Libya]]. This water lay dormant until 1969, when [[Muammar Gaddafi|Muammar al-Gaddafi]] and American [[Armand Hammer]] built the [[Great Man-Made River]] to deliver the Saharan water to the coast. The water largely contributed to irrigation but cost four to ten times more than the crops it produced were worth.[[#refMcNeill2000|McNeill 2000]] p. 155 [292] => [293] => In 1912, the [[Union of South Africa]] created an irrigation department and began investing in water storage infrastructure and irrigation. The government used irrigation and dam-building to further social goals like poverty relief, both by creating construction jobs for poor whites and by creating irrigation schemes to increase white farming. One of their first major irrigation projects was the [[Hartbeespoort Dam]], begun in 1916 as a mechanism to elevate the living conditions of the ‘poor whites’ in the region and eventually completed as a ‘whites only’ employment opportunity.{{cite book |url=https://muse.jhu.edu/book/60573 |title=White South Africa's 'weak sons': Poor whites and the Hartbeespoort Dam |vauthors=((Clynick, T.)) |date=2007 |publisher=Wits University Press |isbn=978-1-86814-669-7 |veditors=((Esterhuysen, A.)), ((Jenkins, T.)), ((Bonner, P.)) |pages=248–274 |chapter=A Search for Origins: Science, history and South Africa's "Cradle of Humankind"}} The [[Pretoria]] irrigation scheme, [[Kammanassie Dam|Kammanassie project]], and Buchuberg irrigation scheme on the [[Orange River]] all followed in the same vein in the 1920s and 30s. [294] => [295] => In Egypt, modern irrigation began with [[Muhammad Ali of Egypt|Muhammad Ali Pasha]] in the mid-1800s, who sought to achieve Egyptian independence from the [[Ottoman Empire|Ottomans]] through increased trade with Europe—specifically cotton exportation.[[#refRoss2017|Ross 2017]] p. 33. His administration proposed replacing the traditional [[flooding of the Nile|Nile basin irrigation]], which took advantage of the annual ebb and flow of the Nile, with irrigation barrages in the lower Nile which better suited cotton production. Egypt devoted 105,000 ha to cotton in 1861, which increased fivefold by 1865. The majority of their exports were shipped to England, and the United-States-Civil-War-induced cotton scarcity in the 1860s cemented Egypt as England's cotton producer.[[#refRoss2017|Ross 2017]] p. 32. As the Egyptian economy became more dependent on cotton in the 20th century, it became more important to control even small Nile floods. Cotton production was more at risk of destruction than more common crops like [[barley]] or wheat.[[#refMcNeill2000|McNeill 2000]] p. 167 After the [[history of Egypt under the British|British occupation of Egypt in 1882]], the British intensified the conversion to perennial irrigation with the construction of the [[Delta Barrage]], the [[Assiut Barrage]], and the first [[Aswan Low Dam|Aswan Dam]]. Perennial irrigation decreased local control over water and made traditional subsistence farming or the farming of other crops incredibly difficult, eventually contributing to widespread peasant bankruptcy and the [[‘Urabi revolt|1879-1882 ‘Urabi revolt]].[[#refRoss2017|Ross 2017]] p. 37-38. [296] => [297] => ==Examples by country== [298] => [299] => {{World topic|Irrigation in|title=Irrigation by country|noredlinks=yes|state=show}} [300] => [301] => == Gallery == [302] => [303] => [304] => Center-pivot irrigation.jpg|upright|The hub of a center-pivot irrigation system [305] => Irrigation drip leaks.jpg|Leaks in [[micro-irrigation]] drip lines [306] => Irrigated blueberries4046.jpg|Sprinkler irrigation of [[Blueberry|blueberries]] in [[Plainville, New York]], United States [307] => Peanuts irrigation.jpg|Irrigation in [[Tamil Nadu, India]] [308] => Irrigation ditch in Montour County, Pennsylvania.JPG|upright|Irrigation ditch in [[Montour County]], Pennsylvania, USA [309] => Sigiriya WaterGardens.JPG|Water gardens in [[Sigiriya]], Sri Lanka [310] => Sprinkler Irrigation - Sprinkler head.JPG|Micro-sprinkler [311] => [312] => [313] => == See also == [314] => {{portal|Agriculture and Agronomy}} [315] => * [[Deficit irrigation]] [316] => * [[Gezira Scheme]] [317] => * [[Irrigation management]] [318] => * [[Irrigation statistics]] [319] => * [[Leaf Sensor]] [320] => * [[Lift irrigation scheme]] [321] => * [[List of countries by irrigated land area]] [322] => * [[Surface irrigation]] [323] => * [[Tidal irrigation]] [324] => * [[Water use in alluvial fans]] [325] => * {{in title|irrigation}} [326] => [327] => == References == [328] => {{reflist|30em}} [329] => [330] => === Sources === [331] => {{refbegin}} [332] => * {{wikicite |ref=refBosshard2009 |reference=Bosshard, Peter. “China Dams the World.” World Policy Journal 26, no. 4 (2009): 43–51. [333] => }} [334] => * {{wikicite |ref=refEkbladh2002 |reference=Ekbladh, David. “‘Mr. TVA’: Grass-Roots Development, David Lilienthal, and the Rise and Fall of the Tennessee Valley Authority as a Symbol for U.S. Overseas Development, 1933-1973.” Diplomatic History 29, no. 3 (Summer 2002): 335–74. [335] => }} [336] => * {{wikicite |ref=refJohnson2019 |reference=Johnson, Matthew P. “Swampy Sugar Lands: Irrigation Dams and the Rise and Fall of Malaria in Puerto Rico, 1898–1962.” Journal of Latin American Studies 51, no. 2 (May 2019): 243–71. https://doi.org/10.1017/S0022216X18000743. [337] => }} [338] => * {{wikicite |ref=refLyster2021 |reference=Lyster, Rosa. “Along the Water.” London Review of Books, May 6, 2021. https://www.lrb.co.uk/the-paper/v43/n09/rosa-lyster/diary. [339] => }} [340] => * {{wikicite |ref=refMcCully2001 |reference=McCully, Patrick. Silenced Rivers: The Ecology and Politics of Large Dams. Enlarged&Updated ed. London ; New York: Zed Books, 2001. [341] => }} [342] => * {{wikicite |ref=refMcNeill2000 |reference=McNeill, John Robert. Something New under the Sun: An Environmental History of the Twentieth-Century World. 1st ed. New York: W.W. Norton & Company, 2000. [343] => }} [344] => * {{wikicite |ref=refParker2020 |reference=Parker, James. “A ‘Juggernaut of Progress’? Irrigation and Statecraft in Late-Colonial Kenya.” International Journal of African Historical Studies 53, no. 3 (September 2020): 335–59. [345] => }} [346] => * {{wikicite |ref=refPeterson2016 |reference=Peterson, Maya. “US to USSR: American Experts, Irrigation, and Cotton in Soviet Central Asia, 1929–32.” Environmental History 21, no. 3 (July 2016): 442–66. https://doi.org/10.1093/envhis/emw006. [347] => }} [348] => * {{wikicite |ref=refRoss2017 |reference=Ross, Corey. Ecology and Power in the Age of Empire: Europe and the Transformation of the Tropical World. First edition. Oxford: Oxford University Press, 2017. [349] => }} [350] => * {{wikicite |ref=refPisani2002 |reference=Pisani, Donald J. Water and American Government: The Reclamation Bureau, National Water Policy, and the West, 1902-1935. Berkeley: University of California Press, 2002. [351] => }} [352] => * {{wikicite |ref=refVisser2018 |reference=Visser, Wessel. “Water as Agent for Social Change, 1900–1939 : Two Case Studies of Developmental State Approaches in Establishing Irrigation Schemes.” Historia 63, no. 2 (November 2018): 40–61. https://doi.org/10.17159/2309-8392/2018/v63n2a3. [353] => }} [354] => * {{wikicite |ref=refWorster1992 |reference=Worster, Donald. Rivers of Empire: Water, Aridity, and the Growth of the American West. New York ; Oxford, England: Oxford University Press, 1992. [355] => }} [356] => {{refend}} [357] => [358] => == Sources == [359] => {{Free-content attribution [360] => | title = World Food and Agriculture – Statistical Yearbook 2023 [361] => | author = FAO [362] => | publisher = FAO [363] => | documentURL = https://www.fao.org/documents/card/en?details=cc8166en [364] => | license statement URL = https://commons.wikimedia.org/whttps://commons.wikimedia.org/wiki/File:World_Food_and_Agriculture_-_Statistical_Yearbook_2023.pdf [365] => | license = CC BY-SA IGO 3.0 [366] => }} [367] => [368] => == External links == [369] => {{Wiktionary}} [370] => * [http://www.icid.org/ International Commission on Irrigation and Drainage (ICID)] [371] => * [https://web.archive.org/web/20160722103109/http://wqic.nal.usda.gov/irrigation-1 Irrigation] at the Water Quality Information Center, U.S. Department of Agriculture [372] => * [http://www.fao.org/ag/agl/aglw/aquastat/main/index.stm AQUASTAT]: FAO's global information system on water and agriculture [373] => [374] => {{Irrigation by country}} [375] => {{Agricultural water management}} [376] => {{Natural resources}} [377] => {{Wastewater}} [378] => {{Prehistoric technology}} [379] => [380] => {{Authority control}} [381] => [382] => [[Category:Irrigation| ]] [383] => [[Category:Agricultural soil science]] [384] => [[Category:Agronomy]] [385] => [[Category:Environmental issues with water]] [386] => [[Category:Land management]] [387] => [[Category:Water management]] [] => )
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Irrigation

Irrigation is the artificial application of water to agricultural fields, gardens, lawns, and other landscapes to help crops and plants grow. It is an essential practice in areas with insufficient rainfall or where water availability is limited, ensuring the successful cultivation of crops and the maintenance of landscapes.

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It is an essential practice in areas with insufficient rainfall or where water availability is limited, ensuring the successful cultivation of crops and the maintenance of landscapes. The history of irrigation dates back thousands of years, with early civilizations developing various techniques to divert water from rivers, streams, and wells. These methods included simple systems such as furrows and trenches to more complex ones like canals and underground tunnels. Modern irrigation techniques have significantly improved water distribution and efficiency. These include overhead sprinkler systems, drip irrigation, and sub-irrigation methods. Overhead sprinklers distribute water in a manner similar to rain, while drip irrigation delivers small amounts of water directly to the plant root zone, reducing wastage. The benefits of irrigation are manifold. It allows farmers to optimize crop yields, grow crops in arid regions, and provide consistent water supply during dry spells. It also contributes to soil fertility by preventing drought stress and nutrient leaching. Moreover, irrigation systems play a crucial role in maintaining landscapes, gardens, and sports fields, ensuring their health and vitality. However, irrigation also poses challenges and concerns. Mismanagement of water resources can lead to over-irrigation, causing waterlogging, reduced yields, and environmental damage. Excessive water use can deplete aquifers and surface water bodies, leading to long-term water scarcity. Improper irrigation techniques can also result in soil erosion and salinization. Efficient water management practices, including water-saving irrigation technologies and proper scheduling, are essential in mitigating these issues. The use of sensors, weather forecasts, and computer-based irrigation systems helps optimize water usage and minimize wastage. Additionally, the adoption of sustainable practices such as precision irrigation and the reuse of treated wastewater can improve water efficiency and reduce the environmental impact of irrigation. Overall, irrigation is a vital agricultural and landscaping practice that continues to evolve with advancements in technology and water management. It plays a significant role in ensuring food security, supporting economic development, and maintaining the green spaces we enjoy.

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