A review of the predictability and prediction of ENSO

Latif, Mojib; Anderson, David L. T.; Barnett, T. P.; Cane, Mark A.; Kleeman, Richard; Leetmaa, Ants; O’Brien, James J.; Rosati, Anthony; Schneider, Eric D.

doi:10.1029/97jc03413

Cited by 485 publications

(315 citation statements)

References 108 publications

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“…Prediction throughout the tropics on the basis of the empirical diagnostics and numerical modelling has been appraised in a sequence of reviews over the past decades (Hastenrath, 1985(Hastenrath, , 1986(Hastenrath, , 1990(Hastenrath, , 1995a(Hastenrath, ,b, 2002(Hastenrath, , 2006aBarnston et al, 1994Barnston et al, , 1999Palmer and Anderson, 1994;Carson, 1998;Latif et al, 1998, Anderson et al, 1999Nobre et al, 2006). Comparison of performance of the empirical and numerical modelling approaches is called for.…”

Section: Introductionmentioning

confidence: 99%

Climate prediction for Brazil's Nordeste by empirical and numerical modeling methods

Hastenrath

Sun

Moura

2008

Intl Journal of Climatology

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Climate prediction for Brazil's Nordeste meaningfully uses information through January to forecast the rainfall of March–June. Empirical methods developed at the University of Wisconsin use as predictors preseason (October–January) rainfall in the region and January indices of the fields of meridional wind component and sea surface temperature (SST) in the tropical Atlantic and the equatorial Pacific, as input to stepwise multiple regression to predict the March–June rainfall at a network of 27 stations. The training period is 1921–1957, the verification period 1958–1989, and real‐time forecasting continued to 2000. A numerical model (ECHAM4.5) experiment conducted at International Research Institute for Climate and Society at Columbia University used global SST information through January to predict the March–June rainfall at three gridpoints in the Nordeste for the years 1968–1999. For the same predictand, a complementary empirical experiment was conducted using the gridded rainfall observations, again with training period 1921–1957, to yield predictions for 1968–1999. Over this period predicted versus observed rainfall are evaluated in terms of correlation, root‐mean‐square error, absolute error, and bias. Compared with the empirical method the numerical modelling produces larger errors and negative bias. The empirical method captures 59% and the numerical modelling 49% of the variance. Copyright © 2008 Royal Meteorological Society

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Section: Introductionmentioning

confidence: 99%

Climate prediction for Brazil's Nordeste by empirical and numerical modeling methods

Hastenrath

Sun

Moura

2008

Intl Journal of Climatology

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“…Coupled ocean-atmosphere models that can approximate the oceanic state appear able to produce credible forecasts of the E1 Nifio-Southern Oscillation (ENSO) phenomenon (see Latif et al [1998] for a review). A fundamental part of the ENSO forecast problem is the initialization of the ocean component through data assimilation.…”

Section: Introductionmentioning

confidence: 99%

A note on the vertical scales of temperature and salinity and their signature in dynamic height in the western Pacific Ocean: Implications for data assimilation

Maes¹

1999

J. Geophys. Res.

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Abstract. The relationship between the vertical structures of ocean temperature and salinity and their concurrent signature in surface dynamic height anomalies are investigated along the 165øE transequatorial section in the western Pacific Ocean. The data are from conductivity-temperature depth casts made during 28 oceanographic cruises mainly conducted during the 1984-1992 time period as part of the TOGA program. The analysis is based on empirical orthogonal functions that isolate the primary modes of variability, and some possible physical interpretations are suggested. The results show that the first six modes, explaining roughly 80% of the variance, display distinct vertical scales and exhibit coherent and observable signatures in dynamic height which reveal complex patterns in latitude and time. In addition, a method has been developed to reconstruct the temperature and salinity profiles from their signature in the surface dynamic height anomaly using the dominant EOFs. The method is new in the sense that no recourse is made to T-S relations. Residual errors in the vertical after reconstruction are lower than the intrinsic variability, and the method can successfully reproduce the variability at ENSO timescales. The residual error in dynamic height anomalies is lower than I dyn. cm in the equatorial belt, and of the order of 2-4 dyn. cm in the subtropics. The results demonstrate that sea level observations may be translate into temperature and salinity anomalies at depth. The implications for data assimilation in ocean models are discussed. IntroductionThe idea that salinity contributes to ocean dynamics is simply common sense in physical oceanography. Along with temperature, salinity determines the ocean mass and hence, through geostrophy, influences ocean dynamics and currents. Nevertheless, in the tropics, salinity effects have generally been neglected. This may be justified when considering average conditions; the change in density due to changes in temperature across the thermocline is several times greater than the change in density due to changes in salinity across the halocline, while the effect of strong salinity gradients such as reported by Cooper [1988] will be reduced by averaging in climatological data sets such as that of Levitus et al. [1994]. However, when considering variations in temperature, salinity and density, the justification for neglecting salinity begins to break down.Coupled ocean-atmosphere models that can approximate the oceanic state appear able to produce credible forecasts of the E1 Nifio-Southern Oscillation (ENSO) phenomenon (see Latif et al.[1998] for a review). A fundamental part of the ENSO forecast problem is the initialization of the ocean component through data assimilation. This is typically done by using model-data differences in temperature, and sea level are ]. An estimate of the basinwide SSS may be made following the method developed by Reynolds et al. [1998]. Nevertheless, Reynolds et al. [1998] show that SSS alone is not sufficient to estimate model biases ...

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“…On the decadal/interdecadal time scales, ENSO predictability has apparent decadal/interdecadal variations (e.g. Wang 1995; Kirtman and Schopf 1998;Latif et al 1998;Chen et al 2004;Tang et al 2008a). Tang et al…”

Section: Resultsmentioning

confidence: 99%

“…Significant progress has been made in ENSO prediction over the past few decades (e.g., Latif et al 1998;Shukla et. al.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

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ENSO ensemble prediction and predictability for the past 148 years from 1856--2003.

Cheng¹

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A review of the predictability and prediction of ENSO

Cited by 485 publications

References 108 publications

Climate prediction for Brazil's Nordeste by empirical and numerical modeling methods

Climate prediction for Brazil's Nordeste by empirical and numerical modeling methods

A note on the vertical scales of temperature and salinity and their signature in dynamic height in the western Pacific Ocean: Implications for data assimilation

ENSO ensemble prediction and predictability for the past 148 years from 1856--2003.

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