SST predictions with an intermediate
coupled model of the tropical Pacific
contributed by Boris Dewitte1, Dasha Gushchina 2 and Yves duPenhoat 1
1LEGOS/CNES/IRD 14 Av. E. Belin, 31401 Toulouse Cedex
4, France
2Meteorological Department, Geographical Faculty,
Moscow State University, Vorobyevy gory, Moscow, 119899, Russia
Forecasts of the
tropical Pacific SST are presented here using two intermediate coupled models.
The oceanic component consists in a three baroclinic mode ocean and the mixed
layer model differs from the Cane and Zebiak (1987) model in the
parameterization of the vertical advection terms and the basic state (cf.
Dewitte, 2000). The atmospheric component is either a statistical atmospheric
model based on the singular value decomposition (SVD) of observed sea surface
temperature (SST) and wind stress anomalies (see Périgaud et al., 2000) or a
Gill(1980)'s dynamical tropical atmosphere. Initial conditions for the
prediction runs are produced in a coupled mode by nudging the observed winds
(FSU winds for the period 1961-1992, ERS1-2 winds from may 1992 until september
2000, QuikSCAT winds from october 2000) to the simulated winds as in Chen et
al. (1995). The skill of the models for the NINO3 SST index over various
periods and for the 1997-1998 El Niño is presented in Dewitte et al. (2002).
Figure 1 shows model predicted SST and wind
stress anomalies in the tropical Pacific for the next four seasons in the case
of the statistical atmosphere (model 1). These are ensemble averages of 12
forecasts started from Jun-Jul-Aug 2006 conditions. For producing the initial
conditions of the individual forecasts, random noise was added to the system
with an approach similar to Kirtman and Schopf (1998). Model 1 and Model 2 (Figure 2) are predicting slightly warm
conditions for 2006/2007.
Caveat: The
forecasts shown above are experimental in nature. The reader is forewarned that
the methods/forecasts are new and subject to future change and improvement.
References:
Chen, D., S. E. Zebiak, A. J. Busalacchi, and M. A.
Cane, 1995: An improved procedure for El Niño forecasting: Implication for
predictability. Science, 269, 1699-1702.
Dewitte B., 2000: Sensitivity of an intermediate
coupled ocean-atmosphere model of the tropical Pacific to its oceanic vertical
structure. J. Climate, 13, 2363-2388.
Dewitte B., D. Gushchina, Y. duPenhoat and S. Lakeev,
2002: On the importance of subsurface variability for ENSO simulation and
prediction with intermediate coupled models of the Tropical Pacific: A case
study for the 1997-1998 El Niño. Geoph. Res. Lett., 29 (14).
10.1029/2001GL014452.
Gill, A., Some
simple solutions heat-induced tropical circulation. Q. J. R. Meteorol. Soc.,
106, 447-462, 1980.
Kirtman, B. P. and
P. S. Schopf, 1998: Decadal variability in ENSO predictability an prediction, J.
Climate, 11, 2804-2822.
Périgaud C. C.
Cassou, B. Dewitte, L.-L. Fu and D. Neelin, 2000: Using data and intermediate
coupled models for seasonal-to-interannual forecasts. Mon. Wea. Rev.,
128, 3025-3049.
Zebiak, S. E. and
M. A. Cane, 1987: A model El Niño-Southern Oscillation. Mon. Wea. Rev.,
115, 2262-2278.
Figure
Captions:
Fig. 1: model forecast of tropical
Pacific SST (°C) and wind stress (Dyn/cm2) anomalies for SON 2006,
DJF 2006/2007, MAM 2007 and JJA 2007. Each forecast is an ensemble average of
12 sets of prediction runs initialized from wind forced model outputs perturbated
by random noise. Observed data through 31st of August 2006 was used
to produce the forecast. Contour interval 0.5°C. Regions with SSTA amplitude
larger than 0.5°C (lower than -0.5°C) are in yellow-orange (blue). The longuest
wind stress arrow on each map corresponds to the value indicated on the right
hand side. Only wind stress anomalies for which wind modulus is larger than 0.1
Dyn/cm2 are plotted.
Fig.2: same as Fig.
1 but for the coupled model using the dynamical atmosphere.
