Abstract
This study compares the impacts of the El Niño–Southern Oscillation (ENSO) on sea surface temperatures (SSTs) in the tropical North Atlantic Ocean and the tropical Indian Ocean during 1958–2004. It is found that the tropical atmospheric processes mediating the ENSO impacts are different between the two oceans for two reasons. First, the ENSO-induced anomalous Walker circulation is more extensive over the Atlantic than over the Indian Ocean. As a result, the atmospheric bridge (AB) mechanism is the major contributor to the differences in ENSO teleconnections between the two oceans. Secondly, SSTs in the tropical North Atlantic are under a greater control of the atmospheric thermal forcing than those in the tropical Indian Ocean. Due to these different controls, the tropospheric temperature (TT) mechanism also contributes to the different ENSO teleconnections. When compared with the observations, the mean of thirty-seven models from the Coupled Model Intercomparison Project Phase 5 overestimates the ENSO-induced SST response in the tropical Indian Ocean but underestimates the response in the tropical North Atlantic. The overestimation is brought about by a westward extension of ENSO SST anomalies in the models, which causes the AB mechanism to produce an overly strong impact on Indian Ocean SSTs. On the other hand, the underestimation is caused by a weaker-than-observed sensitivity in the simulated Atlantic SSTs to the thermal forcing produced by the TT mechanism.
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1 Introduction
The neighboring tropical Atlantic and Indian Oceans are influenced by the El Niño–Southern Oscillation (ENSO) in the tropical Pacific Ocean which produces profound climate impacts worldwide (e.g., Rasmusson and Carpenter 1982; Kousky et al. 1984; Trenberth et al. 1998; Yu et al. 2012, 2017; Xie et al. 2016). During El Niño (La Niña) events, significant positive (negative) sea surface temperature (SST) anomalies are observed in the tropical Atlantic and Indian Oceans (Enfield and Mayer 1997; Klein et al. 1999; Alexander et al. 2002; Schott et al. 2009). These anomalies typically peak in strength two to four months after ENSO events fully develop (e.g., Klein et al. 1999; Wang et al. 2004). The ENSO-induced Atlantic and Indian Ocean SST variations can not only modulate the climate within the basins (Marengo et al. 2008; Wu et al. 2010) but also exert the feedback influencing ENSO evolution (Yu et al. 2002; Kug and Kang 2006; Ham et al. 2013; Wang et al. 2017).
The atmosphere serves as a key medium for tropical inter-basin teleconnections during ENSO events. Previous studies have identified at least two key tropical atmospheric mechanisms through which ENSO events disturb the atmospheric circulation and thus transmit ENSO’s influences to the neighboring tropical oceans (Cai et al. 2019). One is the atmospheric bridge (AB) mechanism (Klein et al. 1999; Alexander et al. 2002) and the other is the tropospheric temperature (TT) mechanism (Chiang and Sobel 2002; Su et al. 2003, 2005; Chiang and Lintner 2005). The AB mechanism works by displacing the Walker circulation to induce changes in cloudiness and surface wind speeds. These changes alter surface radiative, sensible, and latent heat fluxes, thus producing SST variations underneath (Ramanathan and Collins 1991; Xie and Philander 1994; Ohba and Ueda 2005; Chowdary and Gnanaseelan 2007; Du et al. 2009; Talley et al. 2011). The TT mechanism involves warming (or cooling) of the overlying troposphere. The anomalous temperatures then excite atmospheric Kelvin and Rossby waves (i.e., the Gill-type response) that rapidly spread the local anomalous warming (cooling) throughout the entire tropical troposphere. Subsequently, the warming (cooling), on its arrival over remote oceans, induces SST variations underneath through surface sensible and latent heat fluxes.
The TT mechanism relies on waves propagating through the tropical troposphere. This mechanism may produce similar impacts on the tropical Atlantic and Indian Oceans. In contrast, the AB mechanism works by displacing the Pacific Walker circulation and does not necessarily produce similar impacts on the two neighboring tropical oceans (Gill 1980; Lau and Lim 1982). The AB and TT mechanisms may have different contributions to the observed inter-basin teleconnections of ENSO. In this study, we examine the relative contributions of these two mechanisms in the observations. We also examine if contemporary climate models can realistically simulate both mechanisms. If not, we then study the causes of the model deficiencies. Coupled climate models, such as the Coupled Model Intercomparison Project Phase 5 (CMIP5) models, have been frequently used to project future changes in ENSO and its global impacts (Du et al. 2013; Liu et al. 2013, 2014; Chowdary et al. 2014; Capotondi 2015; Tao et al. 2016). How well the models simulate the AB and TT mechanisms greatly influences their ability to project the ENSO impacts.
Apart from the tropical atmospheric mechanisms, extratropical atmospheric processes also play a role in establishing ENSO’s impacts on the neighboring oceans. The ENSO events can, for example, induce SST variations in the North Atlantic Ocean via the Pacific–North American pattern propagating through the extratropical atmosphere (Giannini et al. 2000). Additionally, ocean dynamics and coupled ocean–atmosphere processes can also modulate the ENSO impacts produced by the AB and TT mechanisms (Shinoda et al. 2004; Du et al. 2009; Deser et al. 2010; Wu and Yeh 2010). Nevertheless, the tropical atmospheric mechanisms (i.e., the AB and TT mechanisms) remain the major processes shaping the responses of neighboring tropical oceans to ENSO (Alexander et al. 2002; García-Serrano et al. 2017).
In this study, we first analyze the observational data in Sect. 3. We then compare the performance of the CMIP5 models in simulating the observed teleconnections and the two mechanisms (Sect. 4). The data sets and methodologies used in this study are described in Sect. 2. Section 5 presents conclusions and discusses the findings of this study.
2 Data sets and methods
The observational and reanalysis data sets used in this study include: (1) the NCEP-NCAR reanalysis (Kalnay et al. 1996) that provides the monthly means of air temperature and three-dimensional winds on a 2.5° × 2.5° grid, as well as surface radiation fluxes on a T62 Gaussian grid; (2) the Hadley Centre Sea Ice and Sea Surface Temperature (HadISST) version 1 data set (Rayner et al. 2003) that provides monthly-mean SSTs on a 1° × 1° grid; (3) the National Oceanic and Atmospheric Administration Extended Reconstructed SST (NOAA ERSST) version 5 data set (Huang et al. 2017) that provides monthly-mean SSTs on a 2° × 2° grid; and (4) the centennial in situ observation-based estimates of the variability of SSTs (COBE SST) data set (Ishii et al. 2005) that provides monthly-mean SSTs on a 1° × 1° grid. The COBE SST data and the ERSST SST data are used to validate the results yielded by the HadISST SST data. The analysis period in this study is 1958–2004. This period is selected because the post-1958 reanalysis data is more reliable (Kistler et al. 2001) and most of the CMIP5 historical simulations are available up to 2004. Historical simulations from thirty-seven (37) CMIP5 models (Table 1) are also used. We use a patch recovery method (Zienkiewicz and Zhu 1992; Jones 1999) to regrid the CMIP5 outputs to common horizontal grids that match the observation grids. The common grids are a 2.5° × 2.5° grid for winds and air temperature, a T62 grid for radiation fluxes, and a 2° × 2° grid for SST. Anomalies in the observations, reanalysis, and CMIP5 simulations are defined as the deviations from the climatological cycle after the linear trend is removed.
A cold tongue index (CTI) is used to quantify ENSO intensity (Paek et al. 2017), which is defined as the SST anomalies (SSTA) averaged within the tropical eastern–central Pacific between 6°N–6°S and 180°–90°W.
We develop a way to quantify the contributions of the AB and TT mechanisms to the ENSO impacts on the neighboring oceans. In order to induce tropical Indian and Atlantic Ocean SSTAs through these mechanisms, the ENSO events have to disturb atmospheric fields over these oceans. The atmospheric anomalies then induce SSTAs underneath. Based on the “quantification of mediated causal effect” method of Runge et al. (2015), the contribution of the AB or TT mechanism to the ENSO inter-basin teleconnections can be quantified as the product of two regression coefficients that separately represent the intensities of the two processes just mentioned. To quantify the contribution of the TT mechanism to the ENSO impacts on tropical Atlantic and Indian Oceans SSTAs, the first regression coefficient (\({R}_{\mathrm{C}\mathrm{T}\mathrm{I}\to {T}_{Trop}}\)) evaluates the direct effect of ENSO on the vertically-averaged (1000–200 hPa) tropical tropospheric temperature anomaly (TTrop) over the these two oceans, and the second regression coefficient (\({R}_{{T}_{Trop}\to \Delta \mathrm{S}\mathrm{S}\mathrm{T}\mathrm{A}}\)) evaluates the direct effect of the mean temperature variation on SSTA tendency (ΔSSTA) underneath. We then quantify the TT mechanism’s contribution to mediating the effect of ENSO on the remote SST as follows:
Seasonal mean values are used in the regression calculations. To calculate the first regression coefficient (\(R_{{{\text{CTI}} \to T_{Trop} }}\)), we regress the seasonal means of the tropical tropospheric mean temperature anomalies over the tropical Atlantic or Indian Ocean region at zero-to-seven-month lag time onto the November–December–January (NDJ) values of the CTI. This means the tropospheric temperature values are the seasonal values taken from NDJ (i.e., zero lag time) up to the following June–July–August (i.e., 7-month lag time). Here, the NDJ is the typical peak season of ENSO. The largest value of these regression coefficients is used as the \({R}_{\mathrm{C}\mathrm{T}\mathrm{I}\to {T}_{Trop}}\) in Eq. (1). To calculate the second regression coefficient (\({R}_{{T}_{Trop}\to \Delta \mathrm{S}\mathrm{S}\mathrm{T}\mathrm{A}}\)), we regress the SSTA tendency in the tropical Atlantic or Indian Ocean region onto the overlying tropospheric mean temperature anomalies at the same season. We also calculate the simultaneous regression from NDJ to the following June–July–August and use the largest regression coefficient as the \({R}_{{T}_{Trop}\to \Delta \mathrm{S}\mathrm{S}\mathrm{T}\mathrm{A}}\) in Eq. (1). To calculate the SSTA tendency, we apply a centered finite difference operator to monthly data and then compute the seasonal means.
A similar procedure is used to quantify the contribution of the AB mechanism as follows:
Here, we replace TTrop with surface wind speed (USurf) and surface radiative flux anomalies (FRad) as the key atmospheric fields of the AB mechanism. We utilize these two atmospheric factors because the AB mechanism can influence SSTA tendencies in the tropical Atlantic or Indian Ocean through both surface sensible and latent heat fluxes (Xie and Philander 1994; Talley et al. 2011) and surface radiative fluxes (Ramanathan and Collins 1991; Klein et al. 1999; Wang 2002). Surface wind speeds play a key role in determining the magnitude of surface sensible and latent heat fluxes. The two regression coefficients in each right-hand-side term of Eq. (2) are calculated in the same way as those in Eq. (1).
3 ENSO inter-basin teleconnections in the observations
To examine the ENSO inter-basin teleconnections, we regress the February–March–April global SSTAs onto the preceding NDJ values of the CTI using the HadISST data set (Fig. 1a). The figure shows that three months after the El Niño peaks in the Pacific, substantial warming appears in the tropical Indian and Atlantic Oceans as well as in the South Atlantic and southeastern Indian Oceans. The strongest tropical warming is located along the equator in the Indian Ocean and to the north of the equator in the Atlantic. We define a tropical Indian Ocean (TIO; 10°N–10°S and 50°E–100°E) index and a tropical North Atlantic (TNA; 5°N–25°N and 15°W–55°W) index to represent the SST variations in these two regions and calculate their lead-lagged regressions onto the NDJ CTI values. As shown in Fig. 1e, f, the TIO response to ENSO peaks two months earlier than the TNA response. These evolutional features are consistent with those found in previous studies (Klein et al. 1999; Alexander et al. 2002; Wang 2002). We repeat the analyses with another two reanalysis SST products (the COBE SST and ERSST data sets) and obtain similar inter-basin teleconnections (Fig. 1b, c).
Figure 1e, f indicates that the peak SST response in the TNA is slightly stronger than that in the TIO. This asymmetric feature is evident when we compare the peak responses in Fig. 2a. The difference between the two responses is statistically significant at 40%, 35%, and 30% level in the HadISST, ERSST, and COBE SST data sets, respectively, when one response value is beyond the confidence limit of the other response value. In the rest of the study, we describe only the results obtained from the HadISST data set, unless otherwise mentioned. To examine the contributions of the AB and TT mechanisms to this asymmetry, we examine the intensities of the two mechanisms using Eqs. (1) and (2). Figure 2b indicates that the AB mechanism produces a larger asymmetry between the TIO and TNA regions than the TT mechanism. Specifically, the AB mechanism induces a SST tendency change in the TNA (0.0924 °C/°C) that is 6.4 times that in the TIO (0.0145 °C/°C), while the TT mechanism induces an SST tendency change in the TNA (0.0621 °C/°C) that is 2.5 times that in the TIO (0.0253 °C/°C). As shown in Eq. (2), the AB mechanism relies on surface wind speed and radiative flux anomalies to produce the ENSO impacts. We find from Fig. 2b that the surface wind speed process contributes more than the radiative flux process to producing the asymmetric ENSO impacts. We repeat these analyses with the COBE SST and ERSST data sets and obtain similar results (not shown).
We further examine the two sub-processes in the AB and TT mechanisms, namely the ENSO impacts on the atmospheric fields over the two oceans (Fig. 2c) and the impacts of the atmospheric fields on local SST tendency (Fig. 2d). For the TT mechanism, ENSO produces comparable impacts on tropical tropospheric mean temperatures over the TNA and TIO (Fig. 2c). This symmetric feature exists because the ENSO influences spread throughout the tropical troposphere rapidly via Rossby and Kelvin waves (Charney 1963; Sobel et al. 2001; Chiang and Sobel 2002). These wave responses can be seen in Fig. 3, in which we regress the tropospheric mean temperature anomalies at one- and seven-month lags onto the NDJ CTI. At the one-month lag (Fig. 3a), a Rossby wave response is seen as a pair of tropospheric temperature anomalies to the west of the ENSO SSTAs, while a Kelvin wave response is seen as temperature anomalies over the equatorial Atlantic to Indian Ocean. At a lag of seven months (Fig. 3b), the wave propagation has produced uniform temperature anomalies throughout the tropical troposphere.
However, as shown in Fig. 2d, the comparable tropospheric temperature anomalies induce a larger SST tendency change in the TNA (0.161 °C/°C) than that in the TIO (0.072 °C/°C). This difference implies that the atmospheric thermal forcing (i.e., atmospheric heat flux) is a more dominant factor in determining the SSTA tendency change in the TNA than in the TIO. This feature supports the suggestions from previous studies that the TNA SSTs are more controlled by atmospheric thermal forcing (e.g., Alexander et al. 2002; Deser et al. 2010), whereas the TIO SSTs are additionally influenced by other factors such as ocean dynamics (e.g., Shinoda et al. 2004; Du et al. 2009; Wu and Yeh 2010). Therefore, the impacts exerted by the TT mechanism on SSTs are asymmetric between the two ocean regions, although the mechanism induces similar atmospheric responses. Statistical significance tests verify the features of the TT mechanism discussed above (see the two leftmost bars in Figs. 4a, 5a).
The different thermal controls also affect how the AB mechanism produces SSTAs in the TIO and TNA, particularly through surface radiative fluxes. Note that surface heat fluxes are defined as positive upward in Fig. 2. We find that the AB mechanism produces comparable anomalies in surface radiative fluxes over the two regions (Fig. 2c), but the anomalous radiative fluxes induce a larger SSTA tendency change in the TNA than in the TIO (Fig. 2d). Therefore, the TIO SSTA tendency is not that sensitive to radiative flux, supporting the suggestion that the TIO SSTs are less thermally controlled than the TNA SSTs. In terms of surface wind speed variations, the AB mechanism produces larger anomalies over the TNA than over the TIO (Fig. 2c), but the anomalous wind speeds induce comparable SSTA tendency changes in both ocean regions (Fig. 2d). Statistical significance tests verify the features of the AB mechanism discussed above (see the two leftmost bars in Figs. 4b, c, 5b, c).
The surface wind responses to ENSO over the neighboring oceans are related to how the Walker circulation is displaced during the ENSO events. To examine this displacement, we regress December–January–February omega anomalies onto the NDJ CTI (Fig. 6). Note that tropical surface wind anomalies can be visually inferred from the anomalous vertical motions, to which the divergent motions are closely connected (Holton and Hakim 2013). Figure 6a shows that, in the case of El Niño, an anomalous sinking motion occurs to the west of the CTI region, covering the tropical western Pacific and part of the TIO. The regressions of surface wind and surface wind speed anomalies onto the NDJ CTI are shown in Fig. 7a. As shown in this figure, the sinking motion induces surface easterly anomalies over the TIO that attenuate the equatorial westerlies and reduce surface wind speeds. Over the tropical Atlantic, the ENSO events also produce anomalous descent to the east of the eastern Pacific, which covers most of the tropical Atlantic (Fig. 6a). Figure 6b shows that the tropical anomalous descent further generates secondary circulation anomalies to its north. As a result, anomalous southwesterlies prevail over the TNA, counteracting the northeasterly trades and diminishing surface wind speeds (Fig. 7a). Similar features are observed in the following spring (not shown). This secondary circulation impact explains why the largest SSTA response to ENSO in the tropical Atlantic occurs to the north of the equator. In addition, the extratropical atmospheric process (i.e., the Pacific–North American pattern pattern) also contributes to the TNA SST response to ENSO (Giannini et al. 2000). It is evident in Fig. 6a that the anomalous Walker circulation during ENSO extends further into the tropical Atlantic than over the TIO. This asymmetric ENSO impact on the Walker circulations causes a stronger ENSO impact on the surface wind speeds over the TNA than over the TIO.
Our analyses (in Figs. 2, 3, 4, 5, 6, 7) indicate that the asymmetric responses of TNA and TIO SSTAs to ENSO result from two major causes. One is that the SSTs in the TNA are more controlled by atmospheric thermal forcing than the SSTs in the TIO, rendering the comparable tropospheric mean temperature anomalies induced by the TT mechanism and the comparable surface radiative flux anomalies induced by the AB mechanism less effective in changing SSTs in the TIO than in the TNA. The other is that the ENSO-induced Walker circulation anomalies extend further into the TNA than the TIO. Due to its close connection to the anomalous Walker circulation, the AB mechanism (through its impact on surface wind speeds in particular) is the dominant contributor to the asymmetric ENSO effects on the SSTs between the two oceans.
4 ENSO inter-basin teleconnections in CMIP5 model simulations
We use the multi-model mean (MMM) values calculated from the historical simulations of 37 CMIP5 models to examine how effectively the CMIP5 models simulate the TT and AB mechanisms and the resultant SSTA responses in the TIO and the TNA. The MMM values of the three-month lagged regressions of model SSTAs onto the NDJ CTI are shown in Fig. 1d. The figure indicates that the CMIP5 models reproduce the observed SSTA responses in the TIO and the TNA during the ENSO events. The simulated responses reach a maximum in the TIO and TNA about three to four months after ENSO peaks (Fig. 1e, f). However, in contrast to the observations, the simulated TIO warming, in the case of El Niño, is overestimated and lingers longer, whereas the simulated TNA warming is underestimated. The CMIP5 models produce asymmetric ENSO responses between the TNA and the TIO that are statistically significant at 5% level (Fig. 8), but the simulated asymmetry is opposite from the observed asymmetry. This difference is clearly revealed in Fig. 2a, which shows that the peak TIO and TNA responses to ENSO in the observations and in the MMM lie on opposite sides of the 45° diagonal line. This shortcoming of the CMIP5 simulations can have many implications. For example, it implies that the CMIP5 models produce an overly strong capacitor effect of the Indian Ocean, which is an important component of the delayed ENSO impact on the western Pacific and East Asian weather and climate (e.g., Xie et al. 2009, 2016; Liu et al. 2018). Previous studies have also shown that only during the boreal summer of the decaying phase of ENSO will TIO SSTAs exert a significant impact on the western North Pacific anomalous anticyclone (Wu et al. 2009, 2010; Chen et al. 2019). The anomalous anticyclone can modulate surface zonal winds in the tropical western Pacific, speeding up or slowing down the termination or transition of ENSO. Therefore, an overestimation of the TIO SST response to ENSO can also influence the performance of the CMIP5 models in simulating ENSO evolution and diversity (Capotondi et al. 2015; An and Kim 2018; Timmermann et al. 2018; Chen et al. 2019). Figure 8 shows that more than one-third of the models significantly overestimate the SST responses to ENSO in the TIO. Regarding the SST responses to ENSO in the TNA, there are also more than one-third of the models which significantly underestimate the responses.
We explore the causes of the erroneous asymmetry in the CMIP5 models by examining their simulations of the AB and TT mechanisms. For this purpose, we apply the previous mechanism analyses (see Fig. 2) to all 37 CMIP5 models, after which, we compare their MMM values with the observed values in the same figure. Figure 2b shows that the simulated TT mechanism is comparable to that observed in the TIO but underestimated in the TNA, while the simulated AB mechanism is comparable to that observed in the TNA but overestimated in the TIO. The overly weak TT mechanism in the TNA and the overly strong AB mechanism in the TIO are the key causes for the erroneous model simulations of the TNA and TIO responses to ENSO. For the simulated TT mechanism, we find that the CMIP5 models reasonably simulate the tropospheric temperature responses to ENSO (Figs. 2c, 3), but the impact of the tropospheric temperature on the SSTA tendency is underestimated in the TNA (Figs. 2d, 3). Over one-third of the models significantly underestimate the effect of the tropospheric temperature anomalies over the TNA on the underneath SSTA tendency (Fig. 5a). Therefore, the underestimated TT mechanism in the TNA is caused by the underestimated impact of tropospheric temperature on the TNA SSTs rather than the ENSO impact on the tropospheric temperature. The underestimated effect of tropospheric mean temperature on the SSTA tendency is likely to arise from an overestimation of ocean mixed layer depths in the tropical Atlantic Ocean in many ocean models (Noh and Lee 2008; Zhang et al. 2018).
Regarding the AB mechanism, both radiative fluxes and surface wind processes contribute to the overestimated AB mechanism in the TIO (Fig. 2b). We find that the MMM has overly strong ENSO impacts on surface radiative fluxes and wind speeds over the TIO (Fig. 2c). The TIO SSTA tendency also displays a stronger sensitivity to surface radiative flux anomalies in the CMIP5 models than in the observations (Fig. 2d). Why is the simulated AB mechanism overestimated in the TIO? We find that the ENSO-induced anomalous subsidence in the MMM is over the Maritime Continent rather than over the western Pacific as in the observations (Fig. 6a, c). As a result, the ENSO-induced subsidence, the associated radiative flux, and easterly anomalies cover a much larger area of the TIO in the MMM (Fig. 7c, d) than in the observations (cf. Figure 7a, b). The overestimation of the ENSO impacts on wind speeds and radiative fluxes in the CMIP5 models can be attributed to this erroneously westward extension of the ENSO-induced anomalous Walker circulation. In Fig. 9, we regress the equatorial Pacific SSTAs onto the NDJ CTI to compare the observed and simulated SSTA evolutions during ENSO. Obviously, the simulated ENSO SSTAs extend further westward than the observed ones, explaining why the simulated Walker circulation anomalies extend too far westward over the Indian Ocean.
The significance tests show that over one-third of the CMIP5 models examined significantly overestimate the ENSO effects on the surface wind speed (Fig. 4b) and surface radiative fluxes (Fig. 4c) over the TIO, while over one-third of the models significantly overestimate the TIO SSTA tendency’s sensitivity to surface radiative flux anomalies (Fig. 5c).
Overall, compared with the observations, the overly westward-extended ENSO SSTAs in the models intensify the AB mechanism over the TIO. As a result, the ENSO impact on TIO SSTs is overestimated. Meanwhile, an overestimation of the thermal inertia in the upper ocean of the TNA may lead to the underestimation of the ENSO impact on TNA SSTs.
5 Conclusions
In this study, we have examined the impacts of ENSO on the SSTAs over the tropical Atlantic and Indian Oceans and the relative contributions of two atmospheric mechanisms to these impacts. We have also analyzed the CMIP5 historical simulations to determine their reliability in simulating the observed impacts and mechanisms.
The main findings are summarized in Fig. 10. In the observations, ENSO produces a slightly stronger impact on the TNA SSTAs via the AB and TT mechanisms than on the TIO SSTAs. Two major factors lead to the asymmetric impacts. One is that the ENSO-induced anomalous Walker circulation extends further into the tropical Atlantic than into the TIO, which enables the AB mechanism to produce stronger thermal forcing in the Atlantic than in the Indian Ocean. The other is the different relative controls of atmospheric thermal forcing over the SST changes in these two oceans. The SSTA tendency in the TNA is found to be more sensitive to thermal forcing than that in the TIO. As a result, the AB mechanism is a substantial contributor to the asymmetry in the ENSO impacts on the TNA and TIO. The TT mechanism also exerts an asymmetric ENSO impact on the two oceans. This mechanism produces symmetric influences on the tropospheric temperature over the TNA and the TIO, but the TNA’s stronger sensitivity to this thermal forcing (compared to the TIO) results in a stronger ENSO impact on the TNA SSTAs than on the TIO SSTAs.
The MMM of the CMIP5 models overestimates the ENSO impacts on the TIO and underestimates the impacts on the TNA. Our analyses indicate that the overestimated impact on the TIO results from an erroneously westward extension of the simulated ENSO SSTAs, which displaces the ENSO-induced anomalous Walker circulation further toward the Indian Ocean than observed. This erroneously westward circulation then intensifies the ENSO impact on the TIO through the AB mechanism. On the other hand, the underestimated ENSO impact on the TNA mainly arises from a weaker-than-observed TT mechanism over this ocean in the CMIP5 models. The models do reproduce an authentic ENSO impact on the tropospheric temperature over the TNA region, but the TNA SSTAs in the models show a weaker sensitivity to these tropospheric temperature anomalies than the observed. The weaker sensitivity may result from the erroneous mixed layer depths of the tropical Atlantic simulated in the models.
In observations, the asymmetry in the SST response to ENSO between the TNA and TIO is not as large as the asymmetry in the intensities of the AB and TT mechanisms over these two oceans (Fig. 2b). Therefore, there must be other factors affecting the ENSO impacts on the two oceans, such as extratropical atmospheric processes, ocean dynamics, and coupled atmosphere–ocean processes. We, however, do not quantify these oceanic factors due to the scope of this study, and thus, further studies on this topic are needed. Also, it should be noted that we assess in this study the overall performance of the CMIP5 models. Inter-model diversities exist in the simulations of oceanic responses to ENSO (e.g., Du et al. 2013).
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Acknowledgements
The authors thank Dr. Jianhua Lu, Dr. Wenxiu Zhong and the two anonymous reviewers for their invaluable suggestions and inspiring comments. Gratitude also goes to Ms. Ge Tang who helped polish the present paper. This study was supported by the National Key Research and Development Program of China (2016YFA0602703), the National Natural Science Foundation of China (Grants 41690123, 41690120 and 91637208), the Jiangsu Collaborative Innovative Center for Climate Change of China, the Guangzhou Institute of Tropical and Marine Meteorology/Guangdong Provincial Key Laboratory of Regional Numerical Weather Prediction, and the NSF Climate and Large-scale Dynamics Program of US under Grants AGS1505145 and AGS-1833075. The Computational & Information Systems Laboratory at the National Center for Atmospheric Research provides the NCAR Command Language software. The NCEP-NCAR reanalysis, NOAA ERSST, and COBE SST data sets are obtained from the NOAA/OAR/ESRL PSD at https://www.esrl.noaa.gov/psd/, while the HadISST data set is downloaded from the UK Met Office at https://www.metoffice.gov.uk.
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He, S., Yu, JY., Yang, S. et al. ENSO’s impacts on the tropical Indian and Atlantic Oceans via tropical atmospheric processes: observations versus CMIP5 simulations. Clim Dyn 54, 4627–4640 (2020). https://doi.org/10.1007/s00382-020-05247-w
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DOI: https://doi.org/10.1007/s00382-020-05247-w