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Evaporation
• What is evaporation?• How is evaporation measured?• How is evaporation estimated?
• Reading: Applied Hydrology Sections 3.5 and 3.6
• With assistance from Dan Siegel and Marcy Litvak
Evaporation
• What is evaporation?• How is evaporation measured?• How is evaporation estimated?
Evaporation
Evaporation – process by which liquid water becomes water vapor– Transpiration – process by which liquid water
passes from liquid to vapor through plant metabolism
– Evapotranspiration – evaporation through plants and trees, and directly from the soil and land surface
– Potential Evaporation – evaporation from an open water surface or from a well-watered grass surface
Factors Influencing Evaporation
• Energy supply for vaporization (latent heat)– Solar radiation
• Transport of vapor away from evaporative surface– Wind velocity over surface– Specific humidity gradient
above surface• Vegetated surfaces
– Supply of moisture to the surface
– Evapotranspiration (ET)• Potential Evapotranspiration
(PET) – moisture supply is not limited
nR
E
Net radiation
Evaporation
Air Flowu
Evapotranspiration (ET)
Over land surfaces, we cannot distinguish between water vapor that evaporated from the soil and water vapor that was transpired through plants
Evaporation
• What is evaporation?• How is evaporation measured?• How is evaporation estimated?
Evaporation from an Open Water Surface
• Simplest form of evapotranspiration– This is the amount of water lost from lakes and reservoirs– Often estimating by measuring the loss from a National
Weather Service Class A pan
• This is referred to as Potential Evapotranspiration (ETp) because it is the maximum potential rate of ET under the given meteorological conditions
Lysimeters
Measurement of evapotranspiration
Flux Towers (Marcy Litvak)
Flux tower instruments
IRGA
3-D Sonic anemometer
Net radiometerPyrronometer
Quantumsensor
Flux tower instruments
Air Temperature at 1m and 10m
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/040
5
10
15
20
25
30
35
40
t_hmp_10m
Freeman Ranc Flux Tower (Marcy Litvak)
Vapor Pressure and Saturated Vapor Pressure (kPa)
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/040
1
2
3
4
5
6
e_Avge_sat_Avg
Relative Humidity at 1m and 10m
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/040
0.2
0.4
0.6
0.8
1
rh_hmp_10m
Average = 0.61
Average = 0.71
Wind Speed (m/s)
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/040
5
10
15
20
25
Net Radiation (W/m2)
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/04
-100
0
100
200
300
400
500
600
700
800
ET -Eddy covariance method
• Measurement of vertical transfer of water vapor driven by convective motion
• Directly measure flux by sensing properties of eddies as they pass through a measurement level on an instantaneous basis
• Statistical tool
Basic Theory
Mean
Fluctuation
Instantaneous signal
InstantaneousPerturbation from
The mean
All atmospheric entities show short-period fluctuations about their long term mean value
Time averaged property
Turbulent mixing
Propterties carried by eddies:Mass, density ρVertical velocity w
Volumetric content qv
Temperature T
Sensible Heat Flux (W/m2)
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/04
-200
-100
0
100
200
300
400
500
Latent Heat Flux (W/m2)
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/04
-200
-100
0
100
200
300
400
500
Evaporation (mm/day)
8/5/04 8/6/04 8/7/04 8/8/04 8/9/04 8/10/04 8/11/04 8/12/04 8/13/04 8/14/04 8/15/04
-4
0
4
8
12
16
20
Average = 3.15 mm/day
Energy Balance Method
Can directly measure these variables
How do you partition H and E??
Evaporation
• What is evaporation?• How is evaporation measured?• How is evaporation estimated?
Energy Balance Method
28.4 W 𝑚2
×𝐽 /𝑠𝑊
×1𝑔
2450 𝐽×
3600 𝑠1h𝑟
×24 h𝑟1𝑑𝑎𝑦
×𝑚3
1000𝑘𝑔×
1𝑘𝑔1000𝑔
×1000𝑚𝑚
1𝑚=1
𝑚𝑚𝑑𝑎𝑦
𝜌 𝑤
𝐸𝑇=E28.4
=1
28.4(𝑅𝑛−𝐺− 𝐻−𝑊 )
The maximum radiative evaporation rate Er =
Velocity Profile
• Determining momentum transfer requires knowing velocity profile
• Flow of air over land or water – log velocity profile
0 1 2 3 40
1
2
3
4
Velocity (u)
Ele
va
tio
n (
z))ln()(
0
*
z
z
k
uzu
/0* u Shear velocity
Von Karman constant Roughness heightk
)ln()(0
*
z
z
k
uzu
0Wall shear stress
0z
zk
u
dz
du 1* Velocity gradient
Aerodynamic Method
• Include transport of vapor away from water surface as function of: – Humidity gradient above
surface– Wind speed across surface
• Upward vapor flux
• Upward momentum flux12
21
zz
qqK
dz
dqKm
vvwa
vwa
nR
E
Net radiation
Evaporation
Air Flow
12
12
zz
uuK
dz
duK mama
12
21
uuK
qqKm
m
vvw
Aerodynamic Method
• Log-velocity profile
• Momentum flux
nR
E
Net radiation
Evaporation
Air Flow
12
21
uuK
qqKm
m
vvw
oZ
Z
ku
uln
1
*
2
12
12
ln
ZZ
uuka
212
122
ln21
ZZK
uuqqkKm
m
vvaw
Thornthwaite-Holzman Equation
u
Z
Aerodynamic Method
• Often only available at 1 elevation
• Simplifying
AEm w
nR
E
Net radiation
Evaporation
Air Flow
212
122
ln21
ZZK
uuqqkKm
m
vvaw
uqv and
22
22
ln
622.0
o
aasa
ZZP
ueekm
aasa eeBE
22
22
ln
622.0
ow
a
ZZP
ukB
2 @ pressure vapor Zea
What is B?
• Imagine ET as an electrical analog
• The potential difference V = (eas – ea)
• The resistance of the atmosphere to heat transfer is ra
• ET, the flux, is analogous to the current, so
ET = V / R = (eas – ea)/ra
Thus
aasa eeBE
𝐵 1/𝑟𝑎
Combined Method
• Evaporation is calculated by– Aerodynamic method
• Energy supply is not limiting– Energy method
• Vapor transport is not limiting
• Normally, both are limiting, so use a combination method
w
hp
K
pKC
622.0
ar EEET
wv
nr l
REE
aasa eeBEE
2)3.237(
4098
T
e
dT
de ss
rEET
3.1
Priestley & Taylor
Example
– Elev = 2 m, – Press = 101.3 kPa, – Wind speed = 3 m/s, – Net Radiation = 200 W/m2, – Air Temp = 25 degC, – Rel. Humidity = 40%,
kJ/kg 244110)25*36.22500(
237010501.23
6
x
Tx
• Use Combo Method to find Evaporation
mm/day10.7997*102441
2003
x
RE
w
nr
Example (Cont.)
– Elev = 2 m, – Press = 101.3 kPa, – Wind speed = 3 m/s, – Net Radiation = 200 W/m2, – Air Temp = 25 degC, – Rel. Humidity = 40%,
Pa3167ase
• Use Combo Method to find Evaporation
mm/day45.7
)day1/s86400(*)m1/mm1000(*126731671054.4 11
xEa
sm/Pa1054.4
1032ln997*3.101
3*19.1*4.0*622.0
ln
622.0 1124
2
22
22
x
xZZP
ukB
ow
a
Pa12673167*4.0* asha eRe
Example (Cont.)
– Elev = 2 m, – Press = 101.3 kPa, – Wind speed = 3 m/s, – Net Radiation = 200 W/m2, – Air Temp = 25 degC, – Rel. Humidity = 40%,
Pa/degC1.67102441*622.0
103.101*1005
622.0 3
3
x
x
K
pKC
w
hp
Pa/degC7.188)253.237(
3167*40982
• Use Combo Method to find Evaporation
738.0
mm/day2.745.7*262.010.7*738.0
ar EEE
262.0
Example
– Net Radiation = 200 W/m2, – Air Temp = 25 degC,
• Use Priestly-Taylor Method to find Evaporation rate for a water body
rEE
3.1 Priestly & Taylor
mm/day10.7rE 738.0
mm/day80.610.7*738.0*3.1 E
Methods of Estimating Actual ET
• Penman-Monteith• Crop Coefficients• Lysimeters• Flux Towers• Satellites
Penman-Monteith Equation
𝐸=∆(𝑅¿¿𝑛−𝐺)+𝜌𝑎𝑐𝑝 (𝑒𝑎𝑠−𝑒𝑎)/𝑟𝑎
𝛾+∆(1+𝑟 𝑠
𝑟𝑎
)¿
• A surface resistance term rs is added to Combined Method to account for soil and vegetation’s tendency to hold onto water
• rs varies based on vegetation cover and soil moisture content
• The wind speed is u at height z • The wind speed is 0 at height zo, which is called the
surface roughness• k=0.41 is the Van Karman constant
Crop Coefficients
• Multiply reference crop ET by a Crop Coefficient and a Soil Coefficient
rcs ETkkET
0 20 40 60 80 100 120 140 1600
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1CORN
Time Since Planting (Days)
Cro
p C
oef
fici
ent,
kc
3.10.2
t;Coefficien Crop
c
c
k
k
10
t;Coefficien Soil
s
s
k
k
ET Actual ET
ET Crop Reference rET
http://www.ext.colostate.edu/pubs/crops/04707.html
Conduction of mass, momentum and energy
• Flux is proportional to the gradient of a potential
dz
du
dz
dCDfm
dz
dTkfh
Momentum flux (laminar flow)
Newton’s law of viscosity
Mass flux Fick’s law of diffusion
Energy flux Fourier’s law of heat conduction
m is dynamic viscosity, D is diffusion coefficient, and k is heat conductivity. Dynamic viscosity (m) is related to kinematic viscosity (n) as m = r n
The direction of transport of extensive properties is transverse to the direction of flow.
Convection
• Energy transfer through the action of turbulent eddies or mass movement of fluids with different velocities.
• Turbulence – mechanism causing greater rate of exchange of mass, energy, and momentum than molecular exchanges
• Unlike conduction, convection requires flowing fluid• Eg. Convection causes vertical air circulation in which
warm air rises and cool air sinks, resulting in vertical transport and mixing of atmospheric properties
Convection of mass, momentum and energy
dz
duKmturb
dz
dCKf wm
dz
dTKCf hph
Momentum flux (turbulent flow)
Km is momentum diffusivity or eddy viscosity
Mass flux
Energy flux Kh is heat diffusivity
Kw is mass diffusivity
• Km is 4-6 orders of magnitude greater than .n
• tturb is the dominant momentum transfer in surface water flow and air flow.
The direction of transport of extensive properties is transverse to the direction of flow.
Potential Evapotranspiration
• Multiply reference crop ET by a Crop Coefficient and a Soil Coefficient
rcs ETkkET
3.10.2
t;Coefficien Crop
c
c
k
k
10
t;Coefficien Soil
s
s
k
k
ET Actual ET
ET Crop Reference rET
http://www.ext.colostate.edu/pubs/crops/04707.html
CORN
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 20 40 60 80 100 120 140 160
Time Since Planting (Days)
Cro
p C
oef
fici
ent,
kc
Resources on the web
• Evaporation maps from NWS climate prediction center– http://www.cpc.ncep.noaa.gov/soilmst/e.shtml
• Climate maps from NCDC– http://www.nndc.noaa.gov/cgi-bin/climaps/climaps.pl
• Evapotranspiration variability in the US– http://geochange.er.usgs.gov/sw/changes/natural/et/
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