william drennan and erik sahlée · william drennan and erik sahlée. rsmas, university of miami,...
TRANSCRIPT
William Drennan and Erik Sahlée
RSMAS, University
of Miami, FloridaMeteorology, Uppsala Universitet, Uppsala, Sweden
On air-sea fluxes in high winds-
a view from the trenches (troughs)
Photo: ASIS direct flux mooring during TS Ernesto
From Fairall
et al 2009, OceanObs, Venice.
Very good agreement (in the mean) for data in range 4 –
16 m/s
Very little data for U > 18 m/s. The few existing data points are from isolated events, and may not be representative of more general conditions.
UM-ASIS datapre-2005:
Only 5 out of 1200 hours for U >18 m/s.
Why so few flux data for U> 18m/s ? This plots shows maximum annual SAR wind speeds in 3x3 deg degrees boxes.
Scatterometer daily winds: High wind events are often transient events
Another reason for the paucity of high wind fluxes are that platforms aren’t reliable in these conditions.
Sensors are also a problem …
ASIS drift track in blue (8 days, 200km)
0
5
10
15
20
U10
(m s
-1)
R/V BrownASIS
71 72 73 74 75 76 77 7890
180
270
360
Win
d D
ir (°
)
Year day 2008
0.05
0.1
0.15
0.2
0.25
0.3Fr
eque
ncy
[Hz]
Wave Spectral Energy(Evolution of 1D spectrum)
2
4
6
Hs [m
]
Significant Wave Height
71 72 73 74 75 76 77 78
0.5
1
1.5
U10
/cp
Year day, 2008
Inverse wave ageFully Developed
0.4 Hz
0.2 Hz
U10=4.2
5
10
15
20
25
Spec
tral e
nerg
y de
nsity
, [m
2 /Hz]
0.4 Hz
0.2 Hz
U10=15.1
Southern Ocean waves: Unimodal, with no spectralseparation between windsea
and swell
0
5
10
15
20
U10
(m s
-1)
R/V BrownASIS
A
A
B
B
Drag coefficient at high winds
0 5 10 15 200
0.5
1
1.5
2
2.5
3
3.5
4x 10
-3
U10 (ms-1)
CD
N
CDN during SoGasex
E1/E2<0.2
0.2<=E1/E2<1
1<=E1/E2<2
2<=E1/E2<4
4<=E1/E2
COARE 3.0
E1 = swell energy No significant
effect of swell on CD E2 = windsea
energy in unimodal
seas of Southern Ocean
Aircraft data
- Eddy correlation- Flight altitudes 35 –
45m- Flights in surface layer-
Fluxes corrected for height using Donelan
1990
GFD CDs are similar to ASIS-SOGasex
CDs, showing enhancement above COARE3 and Smith curves around 16-
20m/s. Above 20m/s, there is no clear trend.
1) Group GPS dropsonde profiles by wind speed at mean BL height2) Assuming mean log profile, extrapolate mean profiles to find zo, thence CD
CD levels off by 40m/s, then decreases at 50m/s
U. Miami ASIST wind wave flume15m x 1m x 1m
Drag levels off at high winds
Figure 4. Vorticity contours obtained via Digital Particle Image Velocimetry (DPIV) in the air flow over wind driven waves [Reul, 1998]. Both wave and air flow are from left to right. (Top) waves of gentle slope – non-separated flow. (Bottom) waves of steep slope – separated flow.
Z(cm)
0 10 20 30 40x (cm)
0
0
6
6
Hypothesis: Flow separation over steep waves reduces effective roughness and drag
BAMS, 2007 “CBLAST”. Also:
French et al 2007 (JAS)
Drennan et al 2007 (JAS)
Zhang et al 2008 (GRL and BLM)
Zhang et al 2009 (JAS)
A: Calibration
B: Eye penetration
Stepped Descents C2
C3 C1
IsabelNOAA GOES-12 VIS image14 Sept 2003, 17:45
St Croix, USVI(colour~ time)
CBLAST data
- Eddy correlation fluxes- Flight altitudes 60 –
400m- Flights in BL, above surface layer-
Momentum fluxes corrected to surface layer using Donelan
1990
Asterisks: CBLAST . Asterisks: CBLAST . FairallFairall et al. (2003); et al. (2003);
------ Smith (1980); Smith (1980); ------ DonelanDonelan et al. (2004); et al. (2004); -------- Powell et al. (2003)Powell et al. (2003)
CBLAST data
- Eddy correlation fluxes- Flight altitudes 60 –
400m- Flights in BL, above surface layer-
Momentum fluxes corrected to surface layer using Donelan
1990 -
Surface winds from SFMR (microwave radiometer)
Again, CD levels off at high U
Drag coefficients in hurricanes٭ CBLAST: French et al 2007◊
Tank: Donelan et al 2004□
GPS Profile: Powell et al 2003
The three high wind results are in qualitative agreement: CD
levels off at high winds. But all are lower than GFD/SOGasex
at 20m/s. These results need to be confirmed with in situ field measurements. Even then, they may not be representative of high latitude conditions, where the wave fields are very different.
0 5 10 15 200.5
1
1.5
2
2.5x 10
-3
Cd1
0n
GFD/SOGasex
What about scalar fluxes ?
Dalton number at high winds
O AGILE (Donelan & Drennan 1995) X HEXOS (Decosmo
et al 1996) ◊
GASEX-ASIS (McGillis
et al 2004)SOWEX (Banner et al 1999)
□
SWADE (Katsaros
et al 1993)∆
CBLAST (Drennan et al 2007)
∇
→
CE
(and CH
) independent of wind to 30 m/s
“Extra”
scatter attributable to sampling
Dalton number at high winds
???
GFD data(Petersen, Renfrew)
●
ASIST flume▲ CBLAST aircraftX
HEXOS tower
CK
~ CE
~ CH
Geophys. Res. Lett, in press
qLTqcqck vlpd ++−= ])1([
Laboratory data indicate constant bulk heat coefficients to 40m/s.No evidence for sea spray enhancement
Ck
= bulk coefficient for moist enthalpy, k
So, what about sea spray ? These are sea spray fluxes (source functions)from the Uni. Leeds CLASP (Compact Lightweight Aerosol Spectrometer –
Norris et al. 2008) mounted near the ASIS sonic anemometer during SOGasex.
10-2 10-1 102 103
How to get fluxes at high winds ? We will be deploying 2 direct
flux moorings off Taiwan during the “Impact of Typhoons of the Pacific”
experiment, June-November 2010. The buoys will measure direct fluxes of momentum, latent and sensible heat, and sea spray, SW and LW radiation, waves, currents, TS, biochemistry). Assuming we have anything left after November, we plan on a long term (1 year) deployment in the Southern Ocean…