An Assessment of Differences in ENSO Mechanisms in a Coupled GCM Simulation

Alvarez-Garcia, F.; Cabos, William; Bevia, María J. Ortiz

doi:10.1175/jcli3607.1

Cited by 7 publications

(4 citation statements)

References 32 publications

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“…The short observational period available (~100 years) does not rule out that they are a reflection of internal variability. It is also possible that low-frequency variability changes the frequency of occurrence of different types of variability in the AZM: [107] found in a GCM simulation that, similarly to ENSO [108], different kinds of Atlantic Niño events can be identified and that their teleconnections to ENSO are of a different nature.…”

Section: Variability At Longer Time Scalesmentioning

confidence: 99%

Tropical Atlantic Variability: Observations and Modeling

2019

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We review the state-of-the-art knowledge of Tropical Atlantic Variability (TAV). A well-developed observing system and sustained effort of the climate modeling community have improved our understanding of TAV. It is dominated by the seasonal cycle, for which some mechanisms have been identified. The interannual TAV presents a marked seasonality with three dominant modes: (i) the Atlantic Zonal Mode (AZM), (ii) the Atlantic Meridional Mode (AMM) and (iii) the variability in the Angola–Benguela Front (ABF). At longer time scales, the AMM is active and low-frequency variations in the strength, periodicity, and spatial structure of the AZM are observed. Also, changes in the mean position of the ABF occur. Climate models still show systematic biases in the simulated TAV. Their causes are model-dependent and relate to drawbacks in the physics of the models and to insufficient resolution of their atmospheric and oceanic components. The identified causes for the biases can have local or remote origin, involving the global ocean and atmospheric circulation. Although there is not a clear consensus regarding the role of model resolution in the representation of the TAV, eddy-resolving ocean models combined with atmospheric models with enhanced horizontal and vertical resolutions simulate smaller biases.

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Section: Variability At Longer Time Scalesmentioning

confidence: 99%

Tropical Atlantic Variability: Observations and Modeling

2019

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“…For this study we use a procedure capable of detecting classes of events (groups that share a distinct evolution), following the technique of AlvarezGarcia et al (2005).…”

Section: Methodsmentioning

confidence: 99%

“…By means of a clustering technique, we identify the main characteristics of simulated ENSO episodes when the model is forced according to the IS92a IPCC scenario (hereinafter SCR run) and compare the results with a second simulation with present day conditions (hereinafter CTR run). This technique has already been used to analyse ENSO characteristics in a simulation of present day climate variability performed with another coupled GCM, the SINTEX model (AlvarezGarcia et al, 2005). Their study stressed the importance of decadal variability in ENSO generation and impacts.…”

Section: Introductionmentioning

confidence: 99%

Impact of global warming on ENSO phase change

2006

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Abstract.We compare the physical mechanisms involved in the generation and decay of ENSO events in a control (present day conditions) and Scenario (Is92a, IPCC 1996) simulations performed with the coupled ocean-atmosphere GCM ECHAM4-OPYC3. A clustering technique which objectively discriminates common features in the evolution of the Tropical Pacific Heat Content anomalies leading to the peak of ENSO events allows us to group into a few classes the ENSO events occurring in 240 years of data in the control and scenario runs. In both simulations, the composites of the groups show differences in the generation and development of ENSO. We present the changes in the statistics of the groups and explore the possible mechanisms involved.

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“…This modified equation system(1),(3) and (5)-(6) was solved numerically (henceforth E2) in a similar way to experiment E1. The value of parameter C T =5.1 was chosen in this experiment, so that the maximum amplitude of variability in T E corresponds to 1.6 o C and so the contribution of both external forcings to this variability would be comparable (that follows from the correlation coefficient between the M(t) and NINO4-index).…”

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confidence: 99%

Modeling of El Niño events using a simple model

Stepanov

2009

Oceanology

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The El Niño Southern Oscillation (ENSO) is modelled with the help of a simple model representing a classical damped oscillator forced by external forcing. Eastern Pacific sea surface temperature (SST) and the mean equatorial Pacific thermocline depth correspond to the roles of momentum and position. The external forcing of the system is supplied by short-period meridional mass fluctuations in the Pacific sector of the Southern Ocean due to the joint effect of the atmospheric variability over the Antarctic Circumpolar Current (ACC), bottom topography and coastlines, and also by the variability of westerly winds in the tropics. Under such conditions the ENSO-like oscillations arise as a result of propagation of signals due to both initial signals appeared in the Southern Ocean and the tropical westerly wind anomaly, that propagate then across the equatorial Pacific by means of fast wave processes. The external forcings are the main factor in establishing the oscillation pattern.

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An Assessment of Differences in ENSO Mechanisms in a Coupled GCM Simulation

Cited by 7 publications

References 32 publications

Tropical Atlantic Variability: Observations and Modeling

Tropical Atlantic Variability: Observations and Modeling

Impact of global warming on ENSO phase change

Modeling of El Niño events using a simple model

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