Post on 25-Apr-2015
CROP COEFFICIENT
This lecture is mainly based on
Benoit Duchemin – IRRIMED 1st Training Workshop – Evapotranspirationand Crop Water Requirements, 8-12 February 2004, Palmyria (Syria)
SOWAMED WORKSHOP
Michel Le Page, June 2008, Amman (Jordania)
1. Reminder of the FAO water budget
Remind : FAO simplified water balance equation
DE[d+1] = DE[d] + ET - R - I + DP
Rain R
ET evapoTranspiration
Irrigat° I
DE ("Depletion") = soil water‘ déficit ’ = amount of waterlost regarding the Total Available Water (TAW) thatthe soil contains for evapotranspiration.
0 ≤ D ≤ TAW0 < D < TAWD = 0 when there is no water left
D = TAW after large water supply
D = TAW - CAW [ mm ]
CAW = Current Available Water
Deep Percolation DP
Effective Rainfall : Amount of water thatreach the soil during a rain event.
-> if R < 0.2 ET0 mm are supposed to beevaporated because of interception by vegetation (important in arid area !!!)
RunOff : believed null (generally lowslopes & occur when D=0) or equal to a fraction of rainfall in case of high slopes.
Deep Percolation : believed null except in case of important water supply. Once the soil fullfilled, DP = additional rain or irrigation (no delay)
The capillary rises are neglected. This assumption is reasonable if the watertable is deep enough (1 meter from the effective rooting zone ?)
Effec-tiverain R
EvapoTranspiration
Irrigat° RunOff
RO
Deep Percolation DP
Remind : FAO simplified water balance equation
Readily Available Water (RAW) Total Available Water (TAW)
Soil = water for evapotranspiration
TAW = 1000 ( θFC - θWP ) . Zr (mm)RAW = p x TAW (mm)
- Zr is the Root Depth- p is the « DepletionFraction » (percentage of water easily transpirable)
Soil = water for evapotranspiration
Irrigation Monitoring (Standard Condition)
When to irrigate (*) Before depletion reaches RAW = p . TAW
(one neccessary to be a crop in Standard Condition
+ disease-free + no N stress + infinite extent… )
How much water ? Depletion losses by evapotranspiration
(*) There is other possible answers, according to the level of water stress (and loss of production) that we accept
Standard condition ( ETC ) for a specific crop= reference condition for the grasses
(well-watered, no disease, completely shading the ground…)
2. Single Crop Coefficient
( Reference = Well - Watered Grass )
( Standard Condition for Other Crops )
FAO-24 (1973, 1977) & FAO-56 (1998)
1 Cultural Coef. (Kc) such as
ETC = Kc. ET0
2 calculation Steps
• ET0
• ETC
ET0
ETC
ET0 x
FAO method : ‘Dual Step/Single Coefficient’ (1)
The cultural coefficient group the difference betweengrass and other crops in terms of evapotranspiration
Basic Equation : ETC = Kc. ET0
for well-watered grass : Kc = 1. (ETC = ET0)
for other crops, Kc account for all the differences with ET of
well-watered grass as expressed in the PM equation
FAO method : ‘Dual Step/Single Coefficient’ (2)
( ) ( )( )
⎟⎟⎠
⎞⎜⎜⎝
⎛++Δ
−+−Δ=
1rr
eTerc
GRnE
a
s
aasata
p
γ
ρ
λ
what is changing in PM ( Rn, ra, rs, fraction cover… ) ?
TRANSPIRATION (ra, rs) :
Crop phenological status
Crop Type
EVAPORATION
Fraction cover
Soil Type
These differences depend of climate !!!
Crop coefficient will changebecause of differences in:
Kc = fn(Phenological stages) (1)
Crop calendar is described with
- 4 phases (Initial, Growth, Maturity, Senescence) linked to
- 3 ‘ key ’ Crop Coefficients :. KcINI --> KcMID --> KcEND .
Init. Growth Maturity Senescence
For annual plant, crop calendar in 4 phases :
• Initial Stage. From sowing to vegetation fraction cover of 10%. Kc = KcINI : constant, generally low, but highly variable with rain and irrigation frequency (evaporat° dominates !).
• Growth (or development stage).Until effective cover (flowering, LAI ≈ 3 ?). KcINI < Kc < KcMID : evaporat°/transpirat° partitioning
• Maturity (or mid-stage). Until start of leave yellowing (?). Kc = KcMID (maximum and constant, generally > 1)
• Senescence (or late-stage). Until total yellowing or yield. KcMID < Kc < KcEND : evaporat°/transpirat° partitioning
(and date of yield !!!)
Kc = fn(Phenological stages) (2)
Phenological stages duration (1)
Forage crop (alfalfa)
FAO Irrigation & Drainage Paper No. 24 provides general lengths for the four stages & the total growing period for various types of climates & locations. This information has been supplemented from other sources and is summarized in Table 11.
In ‘Crop evapotranspiration - Guidelines for computing crop water requirements’ by Allen R.G., Pereira L.S., Raes D. and Smith M. as FAO – I&D Paper No. 56 (1998).
Phenological stages duration (2)
Kc = fn(Crop Type) (1)
2 physical processes :
1) Aerodynamical (height, roughness, structure)Transfer of water is facilitated with more roughness
=> Kc > 1 by a factor 5 – 20 %,
2) Physiological (nature)Because the density and the functioning of stomata
differs from one specie to another=> Dominant group type
annual ~ grassspecific species (citrus, ananas)
It also depends on cultural practices…
TABLE 12. Single (time-averaged) crop coefficients, Kc, and mean maximum plant heights for non stressed, well-managed crops in subhumid climates(RHmin ≈ 45%, u2 ≈ 2 m/s) for use with the FAO Penman-Monteith ETo.
Kc = fn(Crop type) (2)
In ‘Crop evapotranspiration - Guidelines for computing crop water requirements’ by Allen R.G., Pereira L.S., Raes D. and Smith M. as FAO – I&D Paper No. 56 (1998).
Kc_mid & Kc_end variation
Difference in evaporation => Kc_INI variation
coarsetextured soils
Kc ini related to the level of ETo and the interval between irrigations and/or significant rain
When the cover is full-developped, aerodynamical differenceswill be more or less large depending on climatic condition, but coefficients reported in FAO table correspond to a particularclimate (RHmin ≈ 45%, u2 ≈ 2 m/s).
KcMID & KcEND = fn(Climate) !
Kc at mid-season (KcMID)
Humide
Vent Faible
Sec
Vent Fort
For other climaticconditions, Kc are different
Correction formula
In summary…
Calculation steps for FAO ‘ Single Coefficient ’
6 steps :
1. Calculation of reference evapotranspiration ( ETo )
2. Determination of crop calendar
3. Selection of crop coefficients for the 3 key-stages of crop calendar : KcINI , KcMID, KcEND
4. Calculation of climatic condition during maturity andsenescence stages. Correction of KcMID, KcEND
5. Numerical determination of crop coefficients curve
6. Estimation of ETc as ETo x Kc
3. Dual Crop Coefficient
Need for a more complex approachFAO dual coefficient method
Method FAO ‘Dual Crop Coefficient’
FAO-56 (1998) : crop coefficient is explained as thesum of two coefficients that are believed to account
for soil evaporation and plant transpiration
ETC = ( Kcb + Ke ) ET0
Transpiration
Evaporation
(Dual Step : ET0 then ETC)
Basal Crop Coefficient
Assumption = no evaporation (dry soil top layer )
Plant is in standard condition (humid deep soil layer) .
Advantage = constrained value
DEJ = DEJ-1 - RJ - IJ / fw + ETsolJ / few + RPJ
RI
RP
fw = Wetted Fraction --> Irrigation
System
few = Exposed andWetted Fraction
--> Evaporation
(root Zone Percolation term)
Soil top layer water balance
DE
Evaporation phases
Soil capacity to diffuse water
ET0
time
Soil evaporation
phase 1
phase 2
ETsol = Ke ET0 ?
Evaporation Coefficient (Ke)
Ke = min ( Kr . (Kcmax- Kcb) , few . Kcmax )
Kr = 1 during phase 1
Phase 2 : evaporation is limited by water availability in the soil top layer Kr : Ke = Kr . (Kcmax- Kcb)
+ Evaporation comes from the wetted and exposed fraction of soil : Ke ≤ few . Kcmax
Phase 1 : evapotranspiration is limited (by available energy), Kcb + Ke cannot be large than one value ( Kcmax )
( Ke ≤ Kcmax – Kcb )
Evaporation Coefficient Ke (2)
Sol = Readily & Total Evaporable Water = REW & TEW
Ze = top soil layer ( 10 - 15 cm )
(m)
Evaporation Coefficient Ke (3)
DEJ = DEJ-1 - RJ - IJ / fw + ETsolJ / few + DPJ
Phase 1 ( DEJ ≤ REW ) Kr =1
Phase 2 ( DEJ ≥ REW )
Kr = ( TEW - DEj )
/ (TEW -REW)
Ke = min ( Kr . (Kcmax- Kcb) , few . Kcmax )
Three steps :1. Kcmax -> 2. Kr -> 3. Fw & Fc
Ex
Heavy Rain, depletion isempty, and Kr=1
At stage 2 (De>REW), Krbegins to drop
Initial values fromFAO tables andformulas
Wetted soil fraction
fw still constant between watersupply event
Fraction de Sol ExposéExposed and wetted soil fraction
Comparison of single and approaches…
More accurate estimation of ET but the calculation and theformulation is much more complex (and not so clear)
4. Water Stress condition
Water-stressed Condition
similar approach than for evaporation reduction factorneed to consider two buckets (top & root soil layer)
( Pb de la gestion de deux réservoirs )
Mono-Coefficient : ETc_adj = Ks. Kc ET0
Water-stressed Condition
Dual-Coefficient : ETc_adj = ( Kcb.Ks + Ke ) ET0
Conclusion
Many processes are no taken into account (Interception, RunOff, transfer between different soil layer…)
…BUT IT IS OPERATIONAL
0
20
40
60
80
100
120
Mar-03 Apr-03 Jun-03 Aug-03 Oct-03Date
Irrig
atio
n (m
m)
0
0.2
0.4
0.6
0.8
1
1.2
1.4
Applied Irrigations
Total water use 800mm
Ks
stressFAO
Irrigations
Total use 630mm Ks
FAO Method : Example of benefits
Olive trees (Agdal site)
2nd MEDA Water Regional Event on Local Water Management – Marrakech 28-30 April 2008
Crop evapotranspiration - Guidelines forcomputing crop water requirements -FAO Irrigation and drainage paper 56
Richard G. AllenLuis S. PereiraDirk RaesMartin Smith
http://www.fao.org/docrep/X0490E/X0490E00.htm