The Penman–Monteith equation approximates net

evapotranspiration Evapotranspiration (ET) is the combined processes by which water moves from the earth’s surface into the atmosphere. It covers both water evaporation (movement of water to the air directly from soil, canopies, and water bodies) and transpir ...

(ET) from meteorological data, as a replacement for direct measurement of evapotranspiration. The equation is widely used, and was derived by the United Nations

Food and Agriculture Organization The Food and Agriculture Organization of the United Nations (FAO)french: link=no, Organisation des Nations unies pour l'alimentation et l'agriculture; it, Organizzazione delle Nazioni Unite per l'Alimentazione e l'Agricoltura is an intern ...

for modeling potential evapotranspiration ET₀.

Significance

Evapotranspiration contributions are very significant in a watershed's

water balance The law of water balance states that the inflows to any water system or area is equal to its outflows plus change in storage during a time interval. In hydrology, a water balance equation can be used to describe the flow of water in and out of ...

, yet are often not emphasized in results because the precision of this component is often weak relative to more directly measured phenomena, e.g. rain and stream flow. In addition to weather uncertainties, the Penman–Monteith equation is sensitive to vegetation specific parameters, e.g.

stoma In botany, a stoma (from Greek ''στόμα'', "mouth", plural "stomata"), also called a stomate (plural "stomates"), is a pore found in the epidermis of leaves, stems, and other organs, that controls the rate of gas exchange. The pore is bo ...

tal resistance or conductance. Various forms of crop coefficients (K_c) account for differences between specific vegetation modeled and a ''reference evapotranspiration'' (RET or ET₀) standard. Stress coefficients (K_s) account for reductions in ET due to environmental stress (e.g.

soil saturation Water content or moisture content is the quantity of water contained in a material, such as soil (called soil moisture), rock, ceramics, crops, or wood. Water content is used in a wide range of scientific and technical areas, and is expressed as ...

reduces

root In vascular plants, the roots are the organs of a plant that are modified to provide anchorage for the plant and take in water and nutrients into the plant body, which allows plants to grow taller and faster. They are most often below the sur ...

-zone O₂, low

soil moisture Soil moisture is the water content of the soil. It can be expressed in terms of volume or weight. Soil moisture measurement can be based on ''in situ'' probes (e.g., capacitance probes, neutron probes) or remote sensing methods. Water that ent ...

induces

wilt Wilt may refer to: * Wilting, the loss of rigidity of non-woody parts of plants * WILT, An acronym commonly used in instant messaging for 'What I'm Listening To' * Wilt disease, which can refer to a number of different diseases in plants. In lite ...

air pollution Air pollution is the contamination of air due to the presence of substances in the atmosphere that are harmful to the health of humans and other living beings, or cause damage to the climate or to materials. There are many different type ...

effects, and salinity). Models of native vegetation cannot assume crop management to avoid recurring stress.

Equation

Per Monteith’s ''Evaporation and Environment'', the equation is: :

\overset
~ \iff ~
 \overset

:''λ''_v =

Latent heat of vaporization The enthalpy of vaporization (symbol ), also known as the (latent) heat of vaporization or heat of evaporation, is the amount of energy (enthalpy) that must be added to a liquid substance to transform a quantity of that substance into a gas. T ...

. Energy required per unit mass of water vaporized. (J g⁻¹) :''L''_v = Volumetric latent heat of vaporization. Energy required per water volume vaporized. (''L''_v = 2453 MJ m⁻³) :''E'' = Mass water evapotranspiration rate (g s⁻¹ m⁻²) :''ET''_o = Water volume evapotranspired (mm s⁻¹) :Δ = Rate of change of saturation specific humidity with air temperature. (Pa K⁻¹) :''R''_n = Net

irradiance In radiometry, irradiance is the radiant flux ''received'' by a ''surface'' per unit area. The SI unit of irradiance is the watt per square metre (W⋅m−2). The CGS unit erg per square centimetre per second (erg⋅cm−2⋅s−1) is often used ...

(W m⁻²), the external source of energy flux :''G'' = Ground heat flux (W m⁻²), usually difficult to measure :''c''_p =

Specific heat In thermodynamics, the specific heat capacity (symbol ) of a substance is the heat capacity of a sample of the substance divided by the mass of the sample, also sometimes referred to as massic heat capacity. Informally, it is the amount of he ...

capacity of air (J kg⁻¹ K⁻¹) :''ρ''_a = dry air

density Density (volumetric mass density or specific mass) is the substance's mass per unit of volume. The symbol most often used for density is ''ρ'' (the lower case Greek letter rho), although the Latin letter ''D'' can also be used. Mathematicall ...

(kg m⁻³) :δ''e'' =

vapor pressure Vapor pressure (or vapour pressure in English-speaking countries other than the US; see spelling differences) or equilibrium vapor pressure is defined as the pressure exerted by a vapor in thermodynamic equilibrium with its condensed phase ...

deficit (Pa) :''g''_a =

Conductivity Conductivity may refer to: *Electrical conductivity, a measure of a material's ability to conduct an electric current **Conductivity (electrolytic), the electrical conductivity of an electrolyte in solution ** Ionic conductivity (solid state), ele ...

of air, atmospheric conductance (m s⁻¹) :''g''_s = Conductivity of stoma, surface or stomatal conductance (m s⁻¹) :''γ'' =

Psychrometric constant The psychrometric constant \gamma relates the partial pressure of water in air to the air temperature. This lets one interpolate actual vapor pressure from paired dry and wet thermometer bulb temperature readings. :: \gamma =\frac : \gamm ...

(''γ'' ≈ 66 Pa K⁻¹) Note: Often resistances are used rather than conductivities. :

g_a = \tfrac ~ ~ \And ~ ~ g_s = \tfrac = \tfrac

where r_c refers to the resistance to flux from a vegetation canopy to the extent of some defined boundary layer. The atmospheric conductance ''g''_a accounts for aerodynamic effects like the zero plane displacement height and the roughness length of the surface. The stomatal conductance ''g''_s accounts for effect of leaf density (Leaf Area Index), water stress and CO2 concentration in the air, that is to say to plant reaction to external factors. Different models exist to link the stomatal conductance to these vegetation characteristics, like the ones from P.G. Jarvis (1976) or Jacobs et al. (1996).

Accuracy

While the Penman-Monteith method is widely considered accurate for practical purposes and is recommended by the Food and Agriculture Organization of the United Nations, errors when compared to direct measurement or other techniques can range from -9 to 40%.

Variations and alternatives

FAO 56 Penman-Monteith equation

To avoid the inherent complexity of determining stomatal and atmospheric conductance, the Food and Agriculture Organization proposed in 1998 a simplified equation for a reference evapotranspiration called potential evapotranspiration ''ET''₀. It is defined as the evapotranpiration for " nhypothetical reference crop with an assumed crop height of 0.12 m, a fixed surface resistance of 70 s m-1 and an albedo of 0.23." This reference surface is defined to represent "an extensive surface of green grass of uniform height, actively growing, completely shading the ground and with adequate water". The corresponding equation is: :

ET_o = \frac

:''ET''₀ = Potential evapotranspiration, Water volume evapotranspired (mm day⁻¹) :Δ = Rate of change of saturation specific humidity with air temperature. (Pa K⁻¹) :''R''_n = Net

(MJ m⁻² day⁻¹), the external source of energy flux :''G'' = Ground heat flux (MJ m⁻² day⁻¹), usually equivalent to zero on a day :''T'' = Air temperature at 2m (K) :''u_2'' = Wind speed at 2m height (m⁻¹) :δ''e'' =

deficit (kPa) :''γ'' =

(''γ'' ≈ 66 Pa K⁻¹) N.B.: The coefficient 0.408 and 900 are not unitless but account for the conversion from energy values to equivalent water depths: radiation m day⁻¹= 0.408 radiation J m⁻² day⁻¹ This potential evapotranspiration ET₀ can then be used to evaluate the evapotranspiration rate ET from unstressed plant through crop coefficients K_c: ET = K_c * ET₀.

Variations

The standard methods of the

American Society of Civil Engineers American(s) may refer to: * American, something of, from, or related to the United States of America, commonly known as the "United States" or "America" ** Americans, citizens and nationals of the United States of America ** American ancestry, p ...

modify the standard Penman–Monteith equation for use with an hourly time step. The

SWAT model SWAT (Soil & Water Assessment Tool) is a river basin scale model developed to quantify the impact of land management practices in large, complex watersheds. SWAT is a public domain software enabled model actively supported by the USDA Agricultural R ...

is one of many

GIS A geographic information system (GIS) is a type of database containing geographic data (that is, descriptions of phenomena for which location is relevant), combined with software tools for managing, analyzing, and visualizing those data. In a ...

-integrated hydrologic models estimating ET using Penman–Monteith equations.

Priestley–Taylor

The Priestley–Taylor equation was developed as a substitute to the Penman–Monteith equation to remove dependence on observations. For Priestley–Taylor, only radiation (irradiance) observations are required. This is done by removing the aerodynamic terms from the Penman–Monteith equation and adding an empirically derived constant factor,

\alpha

. The underlying concept behind the Priestley–Taylor model is that an air mass moving above a vegetated area with abundant water would become saturated with water. In these conditions, the actual evapotranspiration would match the Penman rate of potential evapotranspiration. However, observations revealed that actual evaporation was 1.26 times greater than potential evaporation, and therefore the equation for actual evaporation was found by taking potential evapotranspiration and multiplying it by

\alpha

. The assumption here is for vegetation with an abundant water supply (i.e. the plants have low moisture stress). Areas like arid regions with high moisture stress are estimated to have higher

\alpha

values. The assumption that an air mass moving over a vegetated surface with abundant water saturates has been questioned later. The lowest and turbulent part of the atmosphere, the

atmospheric boundary layer In meteorology, the planetary boundary layer (PBL), also known as the atmospheric boundary layer (ABL) or peplosphere, is the lowest part of the atmosphere and its behaviour is directly influenced by its contact with a planetary surface. On Ear ...

, is not a closed box, but constantly brings in dry air from higher up in the atmosphere towards the surface. As water evaporates more easily into a dry atmosphere, evapotranspiration is enhanced. This explains the larger than unity value of the Priestley-Taylor parameter

\alpha

. The proper equilibrium of the system has been derived and involves the characteristics of the interface of the atmospheric boundary layer and the overlying free atmosphere.

History

The equation is named after

Howard Penman Howard Latimer Penman (1909 – 1984) was a British meteorologist. He formulated Penman’s Formula, which is used worldwide by meteorologists and agricultural scientists to assess evaporation rates in different setups (lakes and ponds, lawns, cro ...

and

John Monteith John Lennox Monteith DSc, FRS (3 September 1929 – 20 July 2012) was a British scientist who pioneered the application of physics to biology. He was an authority in the related fields of water management for agricultural production, soil phy ...

. Penman first published his equation in 1948 and Monteith revised it in 1965.

References

External links

Derivation of the equation
{{DEFAULTSORT:Penman-Monteith equation Equations Hydrology Agronomy Meteorological concepts