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Runoff and Evaporation in the
WRF Regional Climate Model
Rachel White
Imperial College London, UK
Prof. Ralf Toumi
• Regional climate model and domain
– The Olifants basin in South Africa
• Standard model of soil water physics
• Evidence for a better model?
– Brooks et al. 2010
• Implementation of new physics in NOAHWRF
• Results - validation of new scheme
WRF Regional Climate Model
• Designed for high
resolutions and
research purposes
• Has previously been
shown to successfully
simulate precipitation
on regional scales.
• Many different options
for physical schemes/
parameterisations
Olifants Basin, South Africa
• Water-stressed
region
• Local population,
agriculture and mining
economy dependent on
water resources
• Runoff important for
future water security
WRF V3.2.1
Nested domain, 12km resolution inner domain (36km outer)
Forcing from ERA40
Standard Soil Water Physics
Precipitation
Evapotranspiration
Infiltration
Surface
Runoff
• New infiltration displaces
existing soil water downwards
• Subsurface runoff is oldest
soil water
• Evaporation and transpiration
occur from soil
Subsurface Runoff
• In reality this occurs on
sloping terrain – lateral
movement within soil.
• Expect water in soil close to
a stream to be similar to water
within the stream.
Brooks et al. 2010: Ecohydrologic
separation of water between trees
and streams
LMWL Expected:
Results:
values from soil and trees close to the stream: similar to streamwater
No soil or tree water similar to streamwater. All lower than the LMWL indicating evaporation.
LMWL = Local meteoric water line, values below this indicate evaporation has occurred
Brooks, J. R., Barnard, H. R., Coulombe, R., and McDonnell, J. J., 2010. Ecohydrologic separation of water between trees and streams in a Mediterranean climate. Nature Geoscience, 3(2):100104.
Brooks et al. 2010: Ecohydrologic
separation of water between trees
and streams
Initial wet season rain events had little impact on streamflow
Brooks et al. conclusions:
• There are two distinct reservoirs within the soil:
– Mobile water expressed in the stream
– Tightly bound water represented by plant water
– Agrees with Dawson and Ehleringer (1991)
• The tightly bound reservoir refills in the first rain
events of the wet season – little response of
streamflow to precipitation during this refill time.
• The tightly bound water does not move within the
soil – it is removed by tensions exerted by plant
roots or direct soil evaporation
Modeling the Tightly Bound
Water Scheme in the NOAH LSM
10yr Simulation Results: Precipitation
Mean Annual Precipitation
WRF_STD
WRF_STD
WRF_TBW
CRU
CRU
ERA40
ERA40
Precipitation, mm/month
120.0
100.0
80.0
RMSEs (mm/month)
WRF_STD: 10.4
WRF_TBW: 11.6
ERA40: 10.6
60.0
40.0
20.0
0.0
Oct
Nov
Dec
Jan
Feb
Mar
Apr May
Jun
Jul
Aug
Sep
10yr Simulation Results: Runoff
Runoff, mm/month
Runoff Climatologies for ERA_STD and ERA_TBW
WRF_STD
WRF_STD
WRF_TBW
DWA (1920‐89)
DWA (1920‐89)
15.0
10.0
5.0
RMSEs (mm/month)
WRF_STD: 5.2
WRF_TBW: 2.0
0.0
Oct Nov Dec Jan Feb Mar Apr May Jun
Jul Aug Sep
• Yearly bias reduced from +120% to +22%
• Reduction significant at 0.99 confidence (Student’s paired Ttest)
• Such reduction in error not achievable by changing existing
parameters within the NOAH Land Surface Model
Impact of TBW scheme
• Modelling present day extremes
Standard 100-yr return value for
surface runoff (mm/day)
TBW 100-yr return value for
surface runoff (mm/day)
Impact of TBW scheme
• Modelling future changes
– Force WRF with CCSM3 data 1979-1999; 20392059
- TBW scheme
Changes to Climatological Runoff:
2040s – 1980s.
simulates greater
decreases
-TBW scheme
simulates smaller
increases
- Overall the TBW
scheme simulates a
greater decrease in
runoff for the future.
Conclusions
•
Evidence that soil water exists in two distinct
reservoirs – tightly bound and mobile soil water.
•
This new physics has been implemented into
the NOAH land surface model within the
WRF regional model.
•
Results show a highly significant improvement in
the simulation of runoff in a semi-arid climate.
•
Likely to improve runoff simulation in regions with similar climate:
significant moisture-controlled evaporation during rain season.
•
No significant impact on precipitation in this region despite
increase in evaporation – may vary in other areas.
White, R. and Toumi, R., 2012. A Tightly Bound Soil‐Water Scheme within an
Atmosphere‐Land‐Surface model. Journal of Hydrology, accepted.
Thank You!
WRF V3.2.1 Model Set-up
WRF double‐moment 6‐class scheme Betts‐Miller‐Janjic scheme convection
Longwave radiation using the RRTM
Shortwave radiation using the Dudhia scheme
Planetary boundary layer by MYNN Level 2.5
Surface layer physics by the corresponding MYNN surface layer scheme. • NOAH Land Surface Model.
• SSTs updated every 6 hours
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