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| [[File:Surface water cycle.svg|thumb|right|260px|Water cycle of the Earth's surface, showing the individual components of transpiration and evaporation that make up evapotranspiration. Other closely related processes shown are [[Surface runoff|runoff]] and [[groundwater recharge]].]]
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| '''Evapotranspiration''' ('''ET''') is the sum of [[evaporation]] and [[plant]] [[transpiration]] from the Earth's land and Ocean surface to the [[atmosphere]]. Evaporation accounts for the movement of water to the air from sources such as the [[soil]], [[canopy interception]], and [[waterbody|waterbodies]]. Transpiration accounts for the movement of water within a [[plant]] and the subsequent loss of water as vapor through [[stomata]] in its [[leaf|leaves]]. Evapotranspiration is an important part of the [[water cycle]]. An element (such as a tree) that contributes to evapotranspiration can be called an '''evapotranspirator'''.<ref>http://www.oslpr.org/download/en/2000/0031.pdf</ref>
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| '''Potential evapotranspiration''' ('''PET''') is a representation of the environmental demand for evapotranspiration and represents the evapotranspiration rate of a short green crop, completely shading the ground, of uniform height and with adequate water status in the soil profile. It is a reflection of the [[energy]] available to evaporate water, and of the [[wind]] available to transport the water vapour from the ground up into the lower [[Earth's atmosphere|atmosphere]]. Actual evapotranspiration is said to equal potential evapotranspiration when there is ample water.
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| ==Evapotranspiration and the water cycle==
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| Evapotranspiration is a significant water loss from [[drainage basin]]s. Types of vegetation and land use significantly affect evapotranspiration, and therefore the amount of water leaving a drainage basin. Because water transpired through leaves comes from the roots, plants with deep reaching roots can more constantly transpire water. [[Herbaceous plant]]s generally transpire less than [[woody plant]]s because they usually have less extensive foliage. [[Conifer]] forests tend to have higher rates of evapotranspiration than [[deciduous]] forests, particularly in the dormant and early spring seasons. This is primarily due to the enhanced amount of precipitation intercepted and evaporated by conifer foliage during these periods.<ref>Swank, W., and Douglass, J. 1974, ''Science.'' 185(4154) 857-859</ref> Factors that affect evapotranspiration include the plant's growth stage or level of maturity, percentage of soil cover, [[solar radiation]], [[humidity]], [[temperature]], and [[wind]]. Isotope measurements indicate transpiration is the larger component of evapotranspiration.<ref>{{cite journal|last=Jasechko|first=Scott|coauthors=Zachary D. Sharp, John J. Gibson, S. Jean Birks, Yi Yi & Peter J. Fawcett|title=Terrestrial water fluxes dominated by transpiration|journal=Nature|date=3 April 2013|year=2013|doi=10.1038/nature11983|url=http://www.nature.com/nature/journal/vaop/ncurrent/full/nature11983.html|accessdate=4 April 2013|pmid=23552893|volume=496|issue=7445|pages=347–50}}</ref>
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| Through evapotranspiration, forests reduce water yield, except in unique ecosystems called [[cloud forests]]. Trees in cloud forests collect the liquid water in fog or low clouds onto their surface, which drips down to the ground. These trees still contribute to evapotranspiration, but often collect more water than they evaporate or transpire.
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| In areas that are not irrigated, actual evapotranspiration is usually no greater than [[Precipitation (meteorology)|precipitation]], with some buffer in time depending on the soil's ability to hold water. It will usually be less because some water will be lost due to [[percolation]] or surface runoff. An exception is areas with high [[water table]]s, where [[capillary action]] can cause water from the groundwater to rise through the [[soil matrix]] to the surface. If potential evapotranspiration is greater than actual precipitation, then soil will dry out, unless [[irrigation]] is used.
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| Evapotranspiration can never be greater than PET, but can be lower if there is not enough water to be evaporated or plants are unable to transpire readily.
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| ==Estimating evapotranspiration==
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| Evapotranspiration can be measured or estimated using several methods.
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| ===Indirect methods===
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| [[Pan evaporation]] data can be used to estimate lake evaporation, but transpiration and evaporation of intercepted rain on vegetation are unknown. There are three general approaches to estimate evapotranspiration indirectly.
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| ====Catchment water balance====
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| Evapotranspiration may be estimated by creating an equation of the water balance of a drainage basin. The equation balances the change in water stored within the basin (S) with inputs and exports:
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| <math>\Delta S = P - ET - Q - D \,\!</math>
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| The input is precipitation (P), and the exports are evapotranspiration (which is to be estimated), streamflow (Q), and [[groundwater recharge]] (D). If the change in storage, precipitation, streamflow, and groundwater recharge are all estimated, the missing flux, ET, can be estimated by rearranging the above equation as follows:
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| <math>ET = P -\Delta S - Q - D \,\!</math>
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| ====Hydrometeorological equations====
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| The most general and widely used equation for calculating reference ET is the [[Penman equation]]. The [[Penman-Monteith]] variation is recommended by the [[Food and Agriculture Organization]].<ref>{{cite book |last=Allen |first=R.G. |coauthors=Pereira, L.S.; Raes, D.; Smith, M. |title=Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements |url=http://www.fao.org/docrep/X0490E/x0490e00.htm |accessdate=2011-06-08 |series=FAO Irrigation and drainage paper 56 |year=1998 |publisher=Food and Agriculture Organization of the United Nations |location=Rome, Italy |isbn=92-5-104219-5 }}</ref> The simpler [[Blaney-Criddle equation]] was popular in the Western [[United States]] for many years but it is not as accurate in regions with higher humidities. Other solutions used includes Makkink, which is simple but must be calibrated to a specific location, and Hargreaves. To convert the reference evapotranspiration to actual crop evapotranspiration, a [[crop coefficient]] and a [[stress coefficient]] must be used. Crop [[coefficient]]s referred to in many hydrological models are themselves the result of equations that describe predictable variation in coefficient values depending upon plant conditions that change during periods for which the model is used. This is because crops are seasonal, perennial plants mature over multiple seasons, and stress responses can significantly depend upon many aspects of plant condition.
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| ====Energy balance====
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| A third methodology to estimate the actual evapotranspiration is the use of the energy balance.
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| <math> \lambda E = R_n - G - H \,\!</math>
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| where λE is the energy needed to change the phase of water from liquid to gas, R<sub>n</sub> is the net radiation, G is the soil heat flux and H is the [[sensible heat flux]]. Using instruments like a [[scintillometer]], soil heat flux plates or radiation meters, the components of the energy balance can be calculated and the energy available for actual evapotranspiration can be solved.
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| The [[SEBAL]] algorithm solves the energy balance at the earth surface using satellite imagery. This allows for both actual and potential evapotranspiration to be calculated on a pixel-by-pixel basis. Evapotranspiration is a key indicator for water management and irrigation performance. [[SEBAL]] can map these key indicators in time and space, for days, weeks or years.<ref>{{cite web|url= http://www.waterwatch.nl/tools0/sebal.html|title= SEBAL_ WaterWatch}}</ref>
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| ===Experimental Method for measuring ET===
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| One method for measuring ET is with a weighing [[lysimeter]]. The weight of a soil column is measured continuously and the change in storage of water in the soil is modeled by the change in weight. The change in weight is converted to units of length based on the surface area of the weighing lysimeter and the unit weight of water. ET is computed as the change in weight plus rainfall minus percolation.
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| ===Eddy covariance===
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| {{main|Eddy covariance}}
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| The most direct method of measuring evapotranspiration is with the [[eddy covariance]] technique in which fast fluctuations of vertical wind speed are correlated with fast fluctuations in atmospheric water [[vapor density]]. This directly estimates the transfer of water vapor (evapotranspiration) from the land (or canopy) surface to the atmosphere.
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| ===Evapotranspiration of urban landscape plants===
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| A review of ET measurement techniques for estimating the water requirements of urban landscape vegetation could be seen [http://www.tandfonline.com/doi/full/10.1080/1573062X.2012.726360]
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| ==Potential evapotranspiration==
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| [[File:Potential evapotranspiration Hawaii.gif|thumb|350px|Monthly estimated potential evapotranspiration and measured pan evaporation for two locations in [[Hawaii]], Hilo and Pahala.]]
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| Potential evapotranspiration (PET) is the amount of water that would be evaporated and transpired if there were sufficient [[water]] available. This demand incorporates the energy available for evaporation and the ability of the lower atmosphere to transport evaporated moisture away from the land surface. PET is higher in the summer, on less cloudy days, and closer to the equator, because of the higher levels of solar radiation that provides the energy for evaporation. PET is also higher on windy days because the evaporated moisture can be quickly moved from the ground or plant surface, allowing more evaporation to fill its place.
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| PET is expressed in terms of a depth of water, and can be graphed during the year (see figure).
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| Potential evapotranspiration is usually measured indirectly, from other climatic factors, but also depends on the surface type, such as free water (for [[lake]]s and [[ocean]]s), the [[soil]] type for bare soil, and the [[vegetation]]. Often a value for the potential evapotranspiration is calculated at a nearby climate station on a reference surface, conventionally short grass. This value is called the reference evapotranspiration, and can be converted to a potential evapotranspiration by multiplying with a surface coefficient. In agriculture, this is called a crop coefficient. The difference between potential evapotranspiration and precipitation is used in [[irrigation scheduling]].
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| Average annual PET is often compared to average annual precipitation, P. The ratio of the two, P/PET, is the [[aridity index]].
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| ==See also==
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| * [[Eddy covariance]] flux (aka eddy correlation, eddy flux)
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| * [[Hydrology (agriculture)]]
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| * [[Hydrologic Evaluation of Landfill Performance]] (HELP)
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| * [[Latent heat flux]]
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| * [[Weap|Water Evaluation And Planning system (WEAP)]]
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| * [[Soil plant atmosphere continuum]]
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| * [[Deficit irrigation]]
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| == References ==
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| <references />
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| ==External links==
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| *[http://bosque.unm.edu/~cleverly/index.html New Mexico Eddy Covariance Flux Network (Rio-ET)]
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| *[http://wwwcimis.water.ca.gov/cimis/welcome.jsp California's Irrigation Management Information System (CIMIS)]
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| *[http://texaset.tamu.edu/ Texas Evapotranspiration Network]
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| *[http://www.llansadwrn-wx.co.uk/evap/lysim.html Use and Construction of a Lysimeter to Measure Evapotranspiration]
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| *[http://ga.water.usgs.gov/edu/watercycleevapotranspiration.html Evapotranspiration, from the U.S. Geological Survey's Water Cycle Web site]
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| *[http://www.washoeet.dri.edu/ Washoe County (NV) Et Project]
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| *[http://itrc.org Irrigation Training and Research Center (ITRC)] Cal Poly, San Luis Obispo
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| *[http://www.ramin.com.au/creekcare/transpiration-benefits-for-urban-catchments-report.shtml Transpiration Benefits For Urban Catchment Management]
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| *[http://www.springerlink.com/content/rt8r8h42r6686237/ Non-Discharging evapotranspiration bed system for wastewater disposal at Lincoln]
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| *[http://test.oncrete.gr/static/progs/eto-2007-10-13.tgz Eto, an application written in python as a library providing the tools to calculate the reference evapotranspiration with a simple console based interface]
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| *[http://mycrop.oncrete.gr myCrop, an opensource crop management application written in java that can calculate among other things evapotranspiration]
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| *[http://www.tandfonline.com/doi/abs/10.1080/1573062X.2012.726360 Evapotranspiration of Urban Vegetation]
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| [[Category:Hydrology]]
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| [[Category:Climatology]]
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| [[Category:Agronomy]]
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| [[Category:Ecological processes]]
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| [[Category:Irrigation]]
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| [[Category:Water conservation]]
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| [[Category:Water and the environment]]
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