Evaluation of WRF PBL Schemes in the Marine Atmospheric Boundary Layer over the Coastal Waters of...
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Transcript of Evaluation of WRF PBL Schemes in the Marine Atmospheric Boundary Layer over the Coastal Waters of...
Evaluation of WRF PBL Schemes in the Marine Atmospheric Boundary Layer over the Coastal
Waters of Southern New England
Matthew J. Sienkiewicz and Brian A. Colle
School of Marine and Atmospheric Sciences, Stony Brook University
Stony Brook, NY
NROW XV12 November 2014
Coastal New England’s Wind Resource
A combination of shallow coastal bathymetry, population density, average wind speed at turbine hub height, and load coincidence make the coastal waters of Southern New England ideal for offshore wind energy.
Winter Spring
Summer Fall
Modeled Seasonal Peak Offshore Wind Resource at 90 meters (hub height). (Dvorak et al. 2012)
Offshore wind resource maps are created using mesoscale models to account for the sparse observations at and above the water surface.
Motivation Offshore wind resource
assessment and operational forecasting are dependent on mesoscale models accurately representing coastal processes
Models are known to have wind speed biases at the surface over the water (Colle et al. 2003)
Studies of WRF PBL scheme performance have been conducted using coastal and offshore towers and wind profilers in the North Sea and Japan
Regional study is needed to address model biases throughout the entire marine boundary layer in the coastal region of southern New England
FINO1 Tower in the North Sea (Neumann and Nolopp 2007)
Model Wind Speed Biases at NDBC Moored Buoy and C-MAN Stations
Wind Speed biases in m s-1. C-MAN Stations are in blue and moored buoys are in red.
• Wind speed biases near the surface vary spatially, diurnally and seasonally
• Near-surface buoys are not representative of above surface winds due to unknown stability/shear profiles
• Accurate representation of MABL winds is partly dependent upon the accuracy of the SST field and the PBL scheme (Ohsawa et al. 2009)
Wind speeds were reduced from the lowest model level (~7.5 meters) to the buoy anemometer height of 5 meters similar to Hsu et al. 1994.
Studies verifying WRF PBL schemes above the water have mostly been limited to the North Sea and Japan.
More validation is needed within the planetary boundary layer above buoy height.
Motivation
What are the short-term forecast biases in the marine boundary layer over the coastal waters of Southern New England?
How do these biases vary with height above the water surface?
Are there particular stability and flow regimes favoring certain PBL wind biases?
Research Questions
Observational Datasets
NDBC Moored Buoys and C-MAN Stations
Cape Wind Meteorological
Mast2003-2011
Long-EZ Aircraft Flights
Combination of buoy, tower, and aircraft observations provides a dataset for model verification throughout the entire marine boundary layer.
20 meters
41 meters
60 meters
5 meters
40 Hz measurements of 3D winds, temperature, pressure and humidity
55 meters
10 meters
Temperature, Pressure
Wind speed, direction
Experimental Design and Model Configuration WRF-ARW (version 3.4.1) Six PBL schemes
Two First-order (YSU, ACM2)
Four TKE-order (MYJ, MYNN2.5, BouLac, QNSE)
NARR initial and boundary conditions (3-hourly)
0.5° NCEP Daily SST 38 vertical levels 30-hour forecasts First 6 forecast hours are
discarded as model spin-up36 km
12 km
4 km
90 run dates randomly selected between 2003-2011 Equally divided between warm season (APR-SEP) and cool
season (OCT-MAR) Equally divided between 00z and 12z model initialization times
CW Tower Wind Speed Biases
COOL SEASON
Error bars represent bootstrap 95% confidence intervals.
• Largest biases found during the day
• Biases increase in magnitude with height
• BouLac scheme shows large biases at night
Cape Wind Composite Profiles
COOL SEASON• Models are under-sheared during the day
• Super-adiabatic lapse rates during cool season
• Too much mixing of lower momentum from below or higher momentum from above
WARM SEASON• Largest Biases found at 20-meter level during night
• Biases decrease in magnitude with height
• BouLac scheme shows increasing biases with height during day
Error bars represent bootstrap 95% confidence intervals.
CW Tower Wind Speed Biases
Cape Wind Tower Composite Profiles
WARM SEASON• Models display too much wind shear below 40 meters
• Too little downward mixing of higher momentum
• Consistently too cool by 1-2 K throughout lower levels (SST errors?)
High SST Variability in the region
National Data Buoy Center
• Western and central Nantucket Sound heats up in the Spring and stays warm into the Fall
• Eastern Nantucket Sound is subjected to strong tidal mixing of cooler water from the Gulf of Maine
• Cold water pools over the Nantucket Shoals
• Westward excursions of cold water south of MV occur under certain flow regimes
NOAA / Rutgers University
Hong et al. 2009
CW TOWER44020
How do the NCEP Daily SST products perform in Nantucket Sound?
• For the 5-year period spanning 2009-2013• Gridded SST products compared with observed
water temperature at buoy location
Large negative warm season bias
What is the relationship between Wind Shear and Stability?
• YSU, ACM2, MYJ and QNSE schemes display too much wind shear in neutral to higher stabilities
• BouLac scheme is under-sheared in higher stabilities
• Models possibly under-sheared in unstable regimes
• Models over-sheared in neutral stability
Bin-averaged Wind Shear vs. Stability
What is the relationship between Wind Speed and Wind Speed Bias?
Bin-Averaged Mean Error by Modeled Wind Speed
Low (high) wind speed biases are found at low (high) modeled wind speeds.
Aircraft Observations during IMPOWR Campaign
• AIMMS-20 instrument• Up to 40 Hz
measurements of temperature, pressure, relative humidity and three-dimensional winds
• Targeted Nantucket Sound, Buzzard’s Bay and offshore waters to the south
• Flights consisted of level flight legs, spirals up to 1500 meters and slant soundings below 1000 meters
Improving the Mapping and Prediction of Offshore Wind Resources (2013-2014)
AIMMS-20Long-EZ Aircraft
Model Set-up for Long-EZ Flights• 24-hour simulations
forced with hourly Rapid Refresh analyses• Prescribed NCEP 1/12th
degree SST• One-way nested 1.333
km grid with 5-minute output used for interpolation of model variables to aircraft flight track
4 km
1.333 km
Strong Southwesterly Flow with Marine LLJ23-JUN-2013 18z SFC ANALYSIS
• Southwesterly flow dominated by Bermuda High
• Land-sea temperature difference of 20 °F
• 40 knot LLJ structure developed over coastal waters and SE Massachusetts
Aircraft Spiral 2200 UTC 23 JUNE 2013fhr22
Too StableToo Cool
Too Strong
Aircraft Cross-section23z 23-JUN-2013SW-NE
STABLE LAYER
>19 m s-1
300
297
294
18
1614 12 10
RAP-WRF PBL SchemesWinds at 300 meters at forecast
hour 23
Most schemes display the observed extent of 18-19 m s-1 winds at 300 meters from Buzzard’s Bay to the south shore of Long Island.
YSU ACM2 MYJ
MYNN2 BouLac QNSE
CHH Sounding 0000 UTC 24 JUNE 2013fhr24
Good Agreement
Too stable, too warm
Too Strong
How do the initial and boundary conditions affect the jet structure?RAP-WRF NAM-
WRFGFS-WRF NARR-
WRF
• RAP-WRF correctly displays extent of strong winds to south shore of Long Island
• NARR-WRF shows weakest jet structure that is retracted to the northeast
Winds at 300 meters and NW-SE Cross-sections for lowest 1 km at f24
NARR-WRF best handles lowest level winds, but under-predicts LLJ
How do the boundary conditions affect the jet structure?
Too Cool
Too Stable
How does the SST field affect the momentum and thermal structures below jet level?
SST Perturbation Experiment• Better represent SST field in
Nantucket Sound by warming the western Sound and cooling the eastern Sound.
• Warmed upstream regions and decreased land/sea contrast to south while increasing it to north
• Maintained continuous SST field
SST Perturbation Experiment Results
• Perturbing the SST field only slightly affected the below-jet thermal, moisture and momentum profiles
Summary of Results• Lowest 60 meters are too stable and too
sheared during the Warm Season, resulting in negative wind speed biases at the 20 meter level• Too unstable during the Cool Season, resulting
in too much mixing of higher momentum from above and negative wind speed biases increasing with height• Combination of coarse SST field and surface
layer scheme over-doing surface fluxes is most likely the cause of misrepresented low-level stability in models• Different initial and boundary conditions yield
more varied results than different PBL schemes Thank you!
http://itpa.somas.stonybrook.edu/LI_WRF