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2. La Niña's Teleconnection to the Indian Ocean Dipole Controlled by Its Longitudinal Position.

Author

Zhang, Teng, Zhang, Wenjun, Jiang, Feng, and Jin, Fei‐Fei

Subjects
LA Nina, EL Nino, OCEAN temperature, WALKER circulation, CLIMATE change, SOUTHERN oscillation
Abstract

While the prominent influence of El Niño‐Southern Oscillation (ENSO) on the Indian Ocean Oscillation (IOD) is widely recognized, intricate relationships between them are often invoked that introduce challenges into seasonal predictions. Previous studies have shown that different flavors of El Niño exhibit distinct associations with the IOD. In this study, we demonstrate that La Niña's teleconnection to the IOD is primarily controlled by its longitudinal position. Westward‐displaced La Niña events tend to produce stronger negative convection anomalies in the central Pacific and more pronounced Walk Circulation anomalies, thereby triggering strong negative IOD events. In contrast, eastward‐displaced La Niña events are usually accompanied by feeble convection response due to the excessively cold conditions in the cold tongue, yielding insignificant IOD response. The pivotal role of La Niña's longitudinal position on the IOD's response is realistically reproduced by targeted pacemaker experiments, providing new insights into inter‐basin climate connections. Plain Language Summary: The tropical Indian Ocean usually witnesses a dipolar pattern of sea surface temperature (SST) anomalies, which is commonly referred to as the Indian Ocean Dipole (IOD). The IOD phenomenon has received much attention due to its profound global impacts, yet its seasonal prediction remains a large challenge for the climate community. The year‐to‐year variability of IOD has usually been linked to the El Niño–Southern Oscillation (ENSO), the predominant interannual climate variability in the tropical Pacific. The relationship between El Niño (i.e., warm phase of ENSO) and the intensity of IOD has been demonstrated in previous studies, which is shown to be dependent on the different El Niño flavors. In this study, we show that the longitudinal position of negative SST anomalies during La Niña events (i.e., cold phase of ENSO) in shaping their connection with IOD. Different from westward‐displaced La Niña events that can drive robust negative IOD events, eastward‐displaced La Niña events do not yield significant IOD anomalies due to the excessively cold conditions prevalent in the eastern Pacific cold tongue region. We highlight the importance of La Niña's longitudinal position in its teleconnection to other ocean basins and the associated regional climate anomalies. Key Points: The La Niña's regulation of Indian Ocean Oscillation (IOD) mainly depends on the La Niña longitudinal positionThe westward‐displaced La Niña events produce significant Walker Circulation anomalies, triggering robust negative IOD eventThe importance of La Niña longitudinal position on the IOD's response can be evidenced by the targeted pacemaker experiments [ABSTRACT FROM AUTHOR]

Published
2024
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4. UNDERSTANDING ENSO DIVERSITY

Author

Capotondi, Antonietta, Wittenberg, Andrew T., Newmaman, Matthew, Di Lorenzo, Emamanuele, Yu, Jin-Yi, Braconnot, Pascacale, Cole, Julia, Dewitte, Boris, Giese, Benjamin, Guilyardi, Eric, Jin, Fei-Fei, Karnauskas, Kristopher, Kirtman, Benjamin, Lee, Tong, Schneider, Niklas, Xue, Yan, and Yeh, Sang-Wook

Published
2015

6. ENSO skewness hysteresis and associated changes in strong El Niño under a CO2 removal scenario.

Author

Liu, Chao, An, Soon-Il, Jin, Fei-Fei, Stuecker, Malte F., Zhang, Wenjun, Kug, Jong-Seong, Yuan, Xinyi, Shin, Jongsoo, Xue, Aoyun, Geng, Xin, and Kim, Soong-Ki

Subjects
EL Nino, INTERTROPICAL convergence zone, OCEAN temperature, SOUTHERN oscillation, CLIMATE change, HYSTERESIS
Abstract

El Niño-Southern Oscillation (ENSO) sea surface temperature (SST) anomaly skewness encapsulates the nonlinear processes of strong ENSO events and affects future climate projections. Yet, its response to CO2 forcing remains not well understood. Here, we find ENSO skewness hysteresis in a large ensemble CO2 removal simulation. The positive SST skewness in the central-to-eastern tropical Pacific gradually weakens (most pronounced near the dateline) in response to increasing CO2, but weakens even further once CO2 is ramped down. Further analyses reveal that hysteresis of the Intertropical Convergence Zone migration leads to more active and farther eastward-located strong eastern Pacific El Niño events, thus decreasing central Pacific ENSO skewness by reducing the amplitude of the central Pacific positive SST anomalies and increasing the scaling effect of the eastern Pacific skewness denominator, i.e., ENSO intensity, respectively. The reduction of eastern Pacific El Niño maximum intensity, which is constrained by the SST zonal gradient of the projected background El Niño-like warming pattern, also contributes to a reduction of eastern Pacific SST skewness around the CO2 peak phase. This study highlights the divergent responses of different strong El Niño regimes in response to climate change. [ABSTRACT FROM AUTHOR]

Published
2023
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7. Resolving the Tropical Pacific/Atlantic Interaction Conundrum.

Author

Jiang, Feng, Zhang, Wenjun, Jin, Fei‐Fei, Stuecker, Malte F., Timmermann, Axel, McPhaden, Michael J., Boucharel, Julien, and Wittenberg, Andrew T.

Subjects
CLIMATE change, EL Nino, OCEAN temperature, SOUTHERN oscillation, COMMUNITIES
Abstract

Understanding the interaction between the tropical Pacific and Atlantic Oceans has challenged the climate community for decades. Typically, boreal summer Atlantic Niño events are followed by vigorous Pacific events of opposite sign around two seasons later. However, incorporating the equatorial Atlantic information to variabilities internal to the Pacific lends no significant additional predictive skill for the subsequent El Niño‐Southern Oscillation (ENSO). Here we resolve this conundrum in a physically consistent frame, in which the nascent onset of a Pacific event rapidly induces an opposite‐signed summer equatorial Atlantic event and the lead correlation of Atlantic over Pacific is a statistical artifact of ENSO's autocorrelation. This Pacific‐to‐Atlantic impact is limited to a short window around late spring due to seasonally‐amplified Atlantic atmosphere‐ocean coupling. This new frame reconciles the discrepancies between the observed and multi‐model simulated inter‐basin relationship, providing a major advance in understanding seasonally‐modulated inter‐basin climate connections as well as their predictability. Plain Language Summary: Previous studies interpreted the observed lead/lag relationship between Atlantic Niño/Niña and Pacific Niño/Niña sea surface temperature anomalies as evidence for a precursory role of the equatorial Atlantic on the development of El Niño–Southern Oscillation (ENSO) events. This study clearly demonstrates that this statistical relationship is not related to Atlantic‐to‐Pacific causality, but can rather be explained by seasonally modulated equatorial Atlantic's response to ENSO. We find that Pacific ENSO events drive equatorial Atlantic events rather than vice versa, and reconcile the apparent discrepancies between the observed and multi‐model simulated tropical Pacific/Atlantic relationship. Key Points: The lead correlation of the equatorial Atlantic over the Pacific is not related to Atlantic‐to‐Pacific causalityThe tropical Pacific/Atlantic interaction is consistent with the nascent onset of Pacific events driving the equatorial Atlantic eventsThe discrepancies between the observed and multi‐model simulated tropical Pacific/Atlantic relationship can be reconciled in this new frame [ABSTRACT FROM AUTHOR]

Published
2023
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19. Future Amplification of Sea Surface Temperature Seasonality Due To Enhanced Ocean Stratification.

Author

Jo, Anila Rani, Lee, June‐Yi, Timmermann, Axel, Jin, Fei‐Fei, Yamaguchi, Ryohei, and Gallego, Angeles

Subjects
OCEAN temperature, SEASONAL temperature variations, EMISSIONS (Air pollution), GENERAL circulation model, CLIMATE change, PLANT phenology, OCEAN-atmosphere interaction
Abstract

In many regions the projected future sea surface temperature (SST) response to greenhouse warming is larger in summer than in winter. What causes this amplification of the SST seasonal cycle has remained unclear. To determine robustness of the projected seasonal cycle intensification and ascertain underlying physical mechanisms we analyze a suite of historical and greenhouse warming simulations conducted with 13 coupled general circulation models in the Coupled Model Intercomparison Project Phase 5. In the Representative Concentration Pathway 8.5 scenario, the amplitude of SST seasonal cycle, defined as the difference between climatological maximum and minimum temperature, increases by 30% ± 20% on average by the end of 21st century. Analysis of a simplified mixed layer heat budget demonstrates that the amplification can be attributed to the increasing upper ocean stratification and hence shoaling of the annual‐mean mixed layer. The projected intensification of SST seasonality may have important implications for future changes in marine ecosystems. Plain Language Summary: One of the robust projected climate changes in response to global warming is the amplification of seasonal cycle of sea surface temperature (SST) with larger warming occurring in summer than in winter, especially in the North Atlantic, North Pacific and South Indian Ocean. Here we investigate the underlying physical mechanisms using a suite of future greenhouse warming simulations. We show that for the high greenhouse gas emission scenario the amplitude of SST seasonality increases over the next 80 years by 30% ± 20% globally. Overall mean ocean warming increases the upper ocean stratification, which leads to a shoaling of the mixed layer. This implies that climatological air‐sea heat fluxes impact a smaller ocean volume, which then leads to an increased SST response. Other heat budget terms play only a secondary role. The increased temperature seasonality could further impact plankton phenology and the climatology of upper ocean CO2. Key Points: Under the high greenhouse gas emission scenario, the seasonal amplitude of sea surface temperature (SST) is projected to increase by 30% ± 20% by the end of 21st centuryThe intensification of SST seasonality is largely due to the shoaling of the annual mean mixed layer depthThe advection term explains about 10%–40% of the change in SST seasonality depending on the region [ABSTRACT FROM AUTHOR]

Published
2022
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20. North Atlantic as a Trigger for Pacific‐Wide Decadal Climate Change.

Author

Yao, Shuai‐Lei, Zhou, Wen, Jin, Fei‐Fei, and Zheng, Fei

Subjects
CLIMATE change, OCEAN temperature, TELECONNECTIONS (Climatology), ROSSBY waves, WESTERLIES, GLOBAL warming
Abstract

The Interdecadal Pacific Oscillation (IPO) features a basin‐scale horseshoe‐like sea surface temperature (SST) anomaly pattern. Its cold‐phase shift around 1999, implicated as a driver for the early‐2000s global warming slowdown, has been potentially linked to the Atlantic warming during the positive‐phase Atlantic Multidecadal Variability (AMV). However, the key mechanism for the trans‐basin Atlantic‐Pacific teleconnection remains debatable. Here, we show that an AMV‐SST cooling can initiate a pan‐Pacific response. The North Atlantic cooling induces westerly wind anomalies over the central‐western equatorial Pacific as Kelvin‐wave responses and easterly wind anomalies over the far‐eastern equatorial Pacific as Rossby‐wave responses. Additionally, anomalous lows are generated over the extratropical North and South Pacific through the midlatitude Rossby wave propagation. The tropical and midlatitude teleconnections act together to develop into a warm‐phase IPO‐like pattern through the wind‐induced latent heat. Our results suggest a potential of advancing the predictability of IPO through a skillful simulation of AMV. Plain Language Summary: The Interdecadal Pacific Oscillation (IPO) is the most prominent mode of decadal climate variability over the whole Pacific basin, characterized by a horseshoe‐shaped sea surface temperature (SST) anomaly pattern. Its Atlantic counterpart, the Atlantic Multidecadal Variability (AMV) is characterized by a basin‐wide SST warming or cooling pattern across the North Atlantic. In recent decades, the Atlantic warming strongly tied to the positive phase of AMV has significantly strengthened the tropical Pacific cooling, contributing to the recent global warming hiatus. Yet, the root cause of the trans‐basin Atlantic‐Pacific teleconnection on decadal timescales remains unclear. In this study, using the idealized pacemaker simulations with an imposed AMV‐SST anomaly pattern in a fully coupled model, we rigorously investigate how an AMV‐SST cooling impacts the Pacific‐basin decadal‐scale climate change. We found that an AMV cooling initiates a tropical Gill‐type response and midlatitude Rossby wave trains. The tropical and midlatitude teleconnections work together to form a warm‐phase IPO‐like SST anomaly pattern. Our results highlight that realistic simulation of the AMV may improve the predictability of the IPO state and predictions of global warming rates. Key Points: The Atlantic Multidecadal Variability cooling can drive an Interdecadal Pacific Oscillation‐like warm‐phase patternThe North Atlantic cooling excites a tropical Gill‐type response and midlatitude Rossby wave train responsesBoth the tropical and midlatitude dynamical pathways are central to the decadal‐scale trans‐basin Atlantic‐Pacific connection [ABSTRACT FROM AUTHOR]

Published
2021
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21. Spurious North Tropical Atlantic precursors to El Niño.

Author

Zhang, Wenjun, Jiang, Feng, Stuecker, Malte F., Jin, Fei-Fei, and Timmermann, Axel

Subjects
EL Nino, CLIMATE change, OCEAN temperature, SOUTHERN oscillation
Abstract

The El Niño-Southern Oscillation (ENSO), the primary driver of year-to-year global climate variability, is known to influence the North Tropical Atlantic (NTA) sea surface temperature (SST), especially during boreal spring season. Focusing on statistical lead-lag relationships, previous studies have proposed that interannual NTA SST variability can also feed back on ENSO in a predictable manner. However, these studies did not properly account for ENSO's autocorrelation and the fact that the SST in the Atlantic and Pacific, as well as their interaction are seasonally modulated. This can lead to misinterpretations of causality and the spurious identification of Atlantic precursors for ENSO. Revisiting this issue under consideration of seasonality, time-varying ENSO frequency, and greenhouse warming, we demonstrate that the cross-correlation characteristics between NTA SST and ENSO, are consistent with a one-way Pacific to Atlantic forcing, even though the interpretation of lead-lag relationships may suggest otherwise. It has been suggested that sea surface temperatures in the North Tropical Atlantic exert strong influence on the evolution of the El Nino Southern Oscillation (ENSO). Here, the authors argue that observed statistics are fully consistent with ENSO driving climate variations in the Atlantic and not vice versa. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Decadal Change of Combination Mode Spatiotemporal Characteristics due to an ENSO Regime Shift.

Author

Jiang, Feng, Zhang, Wenjun, Stuecker, Malte F., and Jin, Fei-Fei

Subjects
EL Nino, ATMOSPHERIC circulation, WESTERLIES, FORECASTING, TIME measurements, SOUTHERN oscillation
Abstract

Previous studies have shown that nonlinear atmospheric interactions between ENSO and the warm pool annual cycle generates a combination mode (C-mode), which is responsible for the termination of strong El Niño events and the development of the anomalous anticyclone over the western North Pacific (WNP). However, the C-mode has experienced a remarkable decadal change in its characteristics around the early 2000s. The C-mode in both pre- and post-2000 exhibits its characteristic anomalous atmospheric circulation meridional asymmetry but with somewhat different spatial structures and time scales. During 1979–99, the C-mode pattern featured prominent westerly surface wind anomalies in the southeastern tropical Pacific and anticyclonic anomalies over the WNP. In contrast, the C-mode-associated westerly anomalies were shifted farther westward to the central Pacific and the WNP anticyclone was farther westward extended and weaker after 2000. These different C-mode patterns were accompanied by distinct climate impacts over the Indo-Pacific region. The decadal differences of the C-mode are tightly connected with the ENSO regime shift around 2000; that is, the occurrence of central Pacific (CP) El Niño events with quasi-biennial and decadal periodicities increased while the occurrence of eastern Pacific (EP) El Niño events with quasi-quadrennial periodicity decreased. The associated near-annual combination tone periodicities of the C-mode also changed in accordance with these changes in the dominant ENSO frequency between the two time periods. Numerical model experiments further confirm the impacts of the ENSO regime shift on the C-mode characteristics. These results have important implications for understanding the C-mode dynamics and improving predictions of its climate impacts. [ABSTRACT FROM AUTHOR]

Published
2020
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23. ENSO Regime Changes Responsible for Decadal Phase Relationship Variations Between ENSO Sea Surface Temperature and Warm Water Volume.

Author

Zhang, Wenjun, Li, Sixu, Jin, Fei‐Fei, Xie, Ruihuang, Liu, Chao, Stuecker, Malte F., and Xue, Aoyun

Subjects
OCEAN temperature, WEATHER forecasting, SEA level, CLIMATE change, EL Nino
Abstract

The relationship between the equatorial Pacific warm water volume (WWV) and El Niño–Southern Oscillation (ENSO) sea surface temperature (SST) has varied considerably on decadal timescales. These changes are strongly related to the occurrence frequency of central Pacific (CP) ENSO events. While both eastern Pacific (EP) and CP ENSO events show clear signatures of WWV recharge/discharge, their phase‐lag relationships between WWV and Niño3.4 SST are different. The WWV usually leads the Niño3.4 SST by two to three seasons during EP ENSO, while the lead time is reduced to one season during CP ENSO. The different phase‐lag relationships can be explained by distinct periodicities of the two ENSO types. Hence, ENSO regime changes associated with decadal predominance of either EP or CP ENSO events can give rise to decadal variations in the statistical WWV‐ENSO SST relationship. We emphasize the importance of identifying these different ENSO types and potentially different ENSO regimes to assess ENSO predictability. Key Points: Relationship between WWV and Niño3.4 SST varies on decadal timescales, corresponding to the occurrence frequency of central Pacific ENSOBoth eastern and central Pacific ENSO events show recharge/discharge signatures but with different WWV/Niño3.4 phase‐lag relationshipsThis difference can be explained by the existence of two different ENSO types characterized by distinct intrinsic periodicities [ABSTRACT FROM AUTHOR]

Published
2019
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24. Recent Acceleration of Arabian Sea Warming Induced by the Atlantic‐Western Pacific Trans‐basin Multidecadal Variability.

Author

Sun, Cheng, Li, Jianping, Kucharski, Fred, Kang, In‐Sik, Jin, Fei‐Fei, Wang, Kaicun, Wang, Chunzai, Ding, Ruiqiang, and Xie, Fei

Subjects
CLIMATE change, OCEAN temperature, GLOBAL warming, ATMOSPHERIC models, ATMOSPHERIC circulation
Abstract

Arabian Sea (AS) warming has been significantly accelerated since the 1990s, in particular in the spring season. Here we link the AS warming changes to the Atlantic multidecadal oscillation (AMO). A set of Atlantic pacemaker experiments with a slab mixed‐layer ocean model successfully reproduces the AS spring multidecadal variability and its connection with the AMO. An atmospheric teleconnection from the Atlantic to the AS in the preceding winter and associated thermodynamic air‐sea feedback is found to be important. The teleconnection can be reestablished by the atmospheric model when the AMO sea surface temperature (SST) and its trans‐basin footprint over the western Pacific are prescribed simultaneously. The western Pacific SST warming associated with the AMO positive phase induces a Gill‐type Rossby wave over the AS, showing anomalously low pressures and converging southerlies that weaken winter northerlies. Thus, the wind‐evaporation‐SST feedback results in and maintains the AS warm SST anomalies to the subsequent spring. Plain Language Summary: The rapid warming of the Arabian Sea (AS) since the 1990s not only has significant impacts on the monsoon climate change and extreme weather events (flood, heat wave, and cyclone) in Arabian Peninsula and Indian subcontinent but also poses increasingly severe risks of damage to the coastal and marine ecosystems. However, the cause of this recent acceleration of AS warming remains unclear. Here using observations and atmosphere‐ocean coupled models, we link the observed AS warming changes to the Atlantic multidecadal oscillation (AMO) and show that more than 70% of AS multidecadal variability can be explained by the AMO. This Atlantic‐AS teleconnection involves atmosphere‐ocean interactions across multiple ocean basins, with a contribution from the western Pacific (WP). The SST footprint of the AMO over the WP acts as a relay for the effect of the AMO on the AS by exciting an atmospheric teleconnection and subsequently thermodynamic feedbacks over the AS. The concurrent cold‐to‐warm phase shift of the AMO and its WP SST footprint since the 1990s contribute constructively to the rapid warming of the AS. Our results highlight an unexpected multiple‐basin interaction at decadal timescales, which plays a key role in the attribution of historical regional SST warming. Key Points: The observed Arabian Sea warming changes (slowdown and acceleration) are linked to the Atlantic multidecadal oscillation for the first timeThe teleconnection involves air‐sea interactions across multiple ocean basins, with a contribution from western Pacific that acts as a relayThe decadal phase shift of Atlantic‐Western Pacific trans‐basin variability since the 1990s contributes to the rapid warming of Arabian Sea [ABSTRACT FROM AUTHOR]

Published
2019
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25. Contrasting Local and Remote Impacts of Surface Heating on Polar Warming and Amplification.

Author

Park, Kiwoong, Kang, Sarah M., Kim, Doyeon, Stuecker, Malte F., and Jin, Fei-Fei

Subjects
EARTH (Planet), GREENHOUSE gas mitigation, TROPOSPHERE, GLOBAL warming, WAVE amplification
Abstract

The polar region has been one of the fastest warming places on Earth in response to greenhouse gas (GHG) forcing. Two distinct processes contribute to the observed warming signal: (i) local warming in direct response to the GHG forcing and (ii) the effect of enhanced poleward heat transport from low latitudes. A series of aquaplanet experiments, which excludes the surface albedo feedback, is conducted to quantify the relative contributions of these two physical processes to the polar warming magnitude and degree of amplification relative to the global mean. The globe is divided into zonal bands with equal area in eight experiments. For each of these, an external heating is prescribed beneath the slab ocean layer in the respective forcing bands. The summation of the individual temperature responses to each local heating in these experiments is very similar to the response to a globally uniform heating. This allows the authors to decompose the polar warming and amplification signal into the effects of local and remote heating. Local polar heating that induces surface-trapped warming due to the large tropospheric static stability in this region accounts for about half of the polar surface warming. Cloud radiative effects act to enhance this local contribution. In contrast, remote nonpolar heating induces a robust polar warming pattern that features a midtropospheric peak, regardless of the meridional location of the forcing. Among all remote forcing experiments, the deep tropical forcing case contributes most to the polar-amplified surface warming pattern relative to the global mean, while the high- latitude forcing cases contribute most to enhancing the polar surface warming magnitude. [ABSTRACT FROM AUTHOR]

Published
2018
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26. The importance of ENSO nonlinearities in tropical pacific response to external forcing.

Author

Karamperidou, Christina, Jin, Fei-Fei, and Conroy, Jessica

Subjects
*CLIMATE change, *GREENHOUSE gases, *OCEAN temperature, *METEOROLOGICAL precipitation, EL Nino
Abstract

Tropical Pacific climate varies at interannual, decadal and centennial time scales, and exerts a significant influence on global climate. Climate model projections exhibit a large spread in the magnitude and pattern of tropical Pacific warming in response to greenhouse-gas forcing. Here, we show that part of this spread can be explained by model biases in the simulation of interannual variability, namely the El Niño/Southern Oscillation (ENSO) phenomenon. We show that models that exhibit strong ENSO nonlinearities simulate a more accurate balance of ENSO feedbacks, and their projected tropical Pacific sea surface temperature warming pattern is closely linked to their projected ENSO response. Within this group, models with ENSO nonlinearity close to observed project stronger warming of the cold tongue, whereas models with stronger than observed ENSO nonlinearity project a more uniform warming of the tropical Pacific. These differences are also manifest in the projected changes of precipitation patterns, thereby highlighting that ENSO simulation biases may lead to potentially biased projections in long-term precipitation trends, with great significance for regional climate adaptation strategies. [ABSTRACT FROM AUTHOR]

Published
2017
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27. ENSO and greenhouse warming.

Author

Cai, Wenju, Santoso, Agus, Wang, Guojian, Yeh, Sang-Wook, An, Soon-Il, Cobb, Kim M., Collins, Mat, Guilyardi, Eric, Jin, Fei-Fei, Kug, Jong-Seong, Lengaigne, Matthieu, McPhaden, Michael J., Takahashi, Ken, Timmermann, Axel, Vecchi, Gabriel, Watanabe, Masahiro, and Wu, Lixin

Subjects
CLIMATE change, GLOBAL warming, WALKER circulation, GREENHOUSE gases, EL Nino
Abstract

The El Niño/Southern Oscillation (ENSO) is the dominant climate phenomenon affecting extreme weather conditions worldwide. Its response to greenhouse warming has challenged scientists for decades, despite model agreement on projected changes in mean state. Recent studies have provided new insights into the elusive links between changes in ENSO and in the mean state of the Pacific climate. The projected slow-down in Walker circulation is expected to weaken equatorial Pacific Ocean currents, boosting the occurrences of eastward-propagating warm surface anomalies that characterize observed extreme El Niño events. Accelerated equatorial Pacific warming, particularly in the east, is expected to induce extreme rainfall in the eastern equatorial Pacific and extreme equatorward swings of the Pacific convergence zones, both of which are features of extreme El Niño. The frequency of extreme La Niña is also expected to increase in response to more extreme El Niños, an accelerated maritime continent warming and surface-intensified ocean warming. ENSO-related catastrophic weather events are thus likely to occur more frequently with unabated greenhouse-gas emissions. But model biases and recent observed strengthening of the Walker circulation highlight the need for further testing as new models, observations and insights become available. [ABSTRACT FROM AUTHOR]

Published
2015
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28. Increased frequency of extreme La Niña events under greenhouse warming.

Author

Cai, Wenju, Wang, Guojian, Santoso, Agus, McPhaden, Michael J., Wu, Lixin, Jin, Fei-Fei, Timmermann, Axel, Collins, Mat, Vecchi, Gabriel, Lengaigne, Matthieu, England, Matthew H., Dommenget, Dietmar, Takahashi, Ken, and Guilyardi, Eric

Subjects
LA Nina, CLIMATOLOGY, SOUTHERN oscillation, CLIMATE change, WEATHER forecasting
Abstract

The El Niño/Southern Oscillation is Earth's most prominent source of interannual climate variability, alternating irregularly between El Niño and La Niña, and resulting in global disruption of weather patterns, ecosystems, fisheries and agriculture. The 1998-1999 extreme La Niña event that followed the 1997-1998 extreme El Niño event switched extreme El Niño-induced severe droughts to devastating floods in western Pacific countries, and vice versa in the southwestern United States. During extreme La Niña events, cold sea surface conditions develop in the central Pacific, creating an enhanced temperature gradient from the Maritime continent to the central Pacific. Recent studies have revealed robust changes in El Niño characteristics in response to simulated future greenhouse warming, but how La Niña will change remains unclear. Here we present climate modelling evidence, from simulations conducted for the Coupled Model Intercomparison Project phase 5 (ref. ), for a near doubling in the frequency of future extreme La Niña events, from one in every 23 years to one in every 13 years. This occurs because projected faster mean warming of the Maritime continent than the central Pacific, enhanced upper ocean vertical temperature gradients, and increased frequency of extreme El Niño events are conducive to development of the extreme La Niña events. Approximately 75% of the increase occurs in years following extreme El Niño events, thus projecting more frequent swings between opposite extremes from one year to the next. [ABSTRACT FROM AUTHOR]

Published
2015
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29. ENSO Seasonal Synchronization Theory.

Author

Stein, Karl, Timmermann, Axel, Schneider, Niklas, Jin, Fei-Fei, and Stuecker, Malte F.

Subjects
ATMOSPHERIC circulation, CLIMATOLOGY observations, GEOPHYSICAL observations, TROPICAL climate, EL Nino, PROBABILITY theory, CLIMATE change
Abstract

One of the key characteristics of El Niño-Southern Oscillation (ENSO) is its synchronization to the annual cycle, which manifests in the tendency of ENSO events to peak during boreal winter. Current theory offers two possible mechanisms to account the for ENSO synchronization: frequency locking of ENSO to periodic forcing by the annual cycle, or the effect of the seasonally varying background state of the equatorial Pacific on ENSO's coupled stability. Using a parametric recharge oscillator (PRO) model of ENSO, the authors test which of these scenarios provides a better explanation of the observed ENSO synchronization. Analytical solutions of the PRO model show that the annual modulation of the growth rate parameter results directly in ENSO's seasonal variance, amplitude modulation, and 2:1 phase synchronization to the annual cycle. The solutions are shown to be applicable to the long-term behavior of the damped model excited by stochastic noise, which produces synchronization characteristics that agree with the observations and can account for the variety of ENSO synchronization behavior in state-of-the-art coupled general circulation models. The model also predicts spectral peaks at 'combination tones' between ENSO and the annual cycle that exist in the observations and many coupled models. In contrast, the nonlinear frequency entrainment scenario predicts the existence of a spectral peak at the biennial frequency corresponding to the observed 2:1 phase synchronization. Such a peak does not exist in the observed ENSO spectrum. Hence, it can be concluded that the seasonal modulation of the coupled stability is responsible for the synchronization of ENSO events to the annual cycle. [ABSTRACT FROM AUTHOR]

Published
2014
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30. ENSO stability in coupled climate models and its association with mean state.

Author

Kim, Seon, Cai, Wenju, Jin, Fei-Fei, and Yu, Jin-Yi

Subjects
ATMOSPHERIC thermodynamics, MATHEMATICAL models of oceanography, SIMULATION methods & models, CLIMATE change, PARAMETER estimation, OCEAN temperature, EL Nino
Abstract

In this study, using the Bjerknes stability (BJ) index analysis, we estimate the overall linear El Niño-Southern Oscillation (ENSO) stability and the relative contribution of positive feedbacks and damping processes to the stability in historical simulations of Coupled Model Intercomparison Project Phase 5 (CMIP5) models. When compared with CMIP3 models, the ENSO amplitudes and the ENSO stability as estimated by the BJ index in the CMIP5 models are more converged around the observed, estimated from the atmosphere and ocean reanalysis data sets. The reduced diversity among models in the simulated ENSO stability can be partly attributed to the reduced spread of the thermocline feedback and Ekman feedback terms among the models. However, a systematic bias persists from CMIP3 to CMIP5. In other words, the majority of the CMIP5 models analyzed in this study still underestimate the zonal advective feedback, thermocline feedback and thermodynamic damping terms, when compared with those estimated from reanalysis. This discrepancy turns out to be related with a cold tongue bias in coupled models that causes a weaker atmospheric thermodynamical response to sea surface temperature changes and a weaker oceanic response (zonal currents and zonal thermocline slope) to wind changes. [ABSTRACT FROM AUTHOR]

Published
2014
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31. Increasing frequency of extreme El Niño events due to greenhouse warming.

Author

Cai, Wenju, Borlace, Simon, Lengaigne, Matthieu, van Rensch, Peter, Collins, Mat, Vecchi, Gabriel, Timmermann, Axel, Santoso, Agus, McPhaden, Michael J., Wu, Lixin, England, Matthew H., Wang, Guojian, Guilyardi, Eric, and Jin, Fei-Fei

Subjects
CLIMATE change, GLOBAL warming, ECOSYSTEMS, FLOODS, CLIMATE in greenhouses
Abstract

El Niño events are a prominent feature of climate variability with global climatic impacts. The 1997/98 episode, often referred to as 'the climate event of the twentieth century', and the 1982/83 extreme El Niño, featured a pronounced eastward extension of the west Pacific warm pool and development of atmospheric convection, and hence a huge rainfall increase, in the usually cold and dry equatorial eastern Pacific. Such a massive reorganization of atmospheric convection, which we define as an extreme El Niño, severely disrupted global weather patterns, affecting ecosystems, agriculture, tropical cyclones, drought, bushfires, floods and other extreme weather events worldwide. Potential future changes in such extreme El Niño occurrences could have profound socio-economic consequences. Here we present climate modelling evidence for a doubling in the occurrences in the future in response to greenhouse warming. We estimate the change by aggregating results from climate models in the Coupled Model Intercomparison Project phases 3 (CMIP3; ref. ) and 5 (CMIP5; ref. ) multi-model databases, and a perturbed physics ensemble. The increased frequency arises from a projected surface warming over the eastern equatorial Pacific that occurs faster than in the surrounding ocean waters, facilitating more occurrences of atmospheric convection in the eastern equatorial region. [ABSTRACT FROM AUTHOR]

Published
2014
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32. Late-twentieth-century emergence of the El Niño propagation asymmetry and future projections.

Author

Santoso, Agus, McGregor, Shayne, Jin, Fei-Fei, Cai, Wenju, England, Matthew H., An, Soon-Il, McPhaden, Michael J., and Guilyardi, Eric

Subjects
CLIMATE change, SOUTHERN oscillation, OCEAN temperature, OCEAN waves, OCEANOGRAPHY, WEATHER forecasting, EL Nino
Abstract

The El Niño/Southern Oscillation (ENSO) is the Earth's most prominent source of interannual climate variability, exerting profound worldwide effects. Despite decades of research, its behaviour continues to challenge scientists. In the eastern equatorial Pacific Ocean, the anomalously cool sea surface temperatures (SSTs) found during La Niña events and the warm waters of modest El Niño events both propagate westwards, as in the seasonal cycle. In contrast, SST anomalies propagate eastwards during extreme El Niño events, prominently in the post-1976 period, spurring unusual weather events worldwide with costly consequences. The cause of this propagation asymmetry is currently unknown. Here we trace the cause of the asymmetry to the variations in upper ocean currents in the equatorial Pacific, whereby the westward-flowing currents are enhanced during La Niña events but reversed during extreme El Niño events. Our results highlight that propagation asymmetry is favoured when the westward mean equatorial currents weaken, as is projected to be the case under global warming. By analysing past and future climate simulations of an ensemble of models with more realistic propagation, we find a doubling in the occurrences of El Niño events that feature prominent eastward propagation characteristics in a warmer world. Our analysis thus suggests that more frequent emergence of propagation asymmetry will be an indication of the Earth's warming climate. [ABSTRACT FROM AUTHOR]

Published
2013
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33. A comparison of climatological subseasonal variations in the wintertime storm track activity between the North Pacific and Atlantic: local energetics and moisture effect.

Author

Lee, Sun-Seon, Lee, June-Yi, Wang, Bin, Jin, Fei-Fei, Lee, Woo-Jin, and Ha, Kyung-Ja

Subjects
CLIMATOLOGY, CLIMATE change, SEASONS, WINTER, STORMS
Abstract

Distinct differences of the storm track-jet relationship over the North Pacific and North Atlantic are investigated in terms of barotropic and baroclinic energetics using NCEP-2 reanalysis data for the period of 1979-2008. From fall to midwinter the Pacific storm track (PST) activity weakens following the southward shift of the Pacific jet, whereas the Atlantic storm track (AST) activity remains steady in position and intensifies regardless of the slight southward shift of the Atlantic jet. This study is devoted to seeking for the factors that can contribute to this conspicuous difference between the two storm tracks on climatological subseasonal variation by analyzing eddy properties and local energetics. Different eddy properties over the two oceans lead to different contribution of barotropic energy conversion to the initiation of storm tracks. In the North Atlantic, meridionally elongated eddies gain kinetic energy efficiently from stretching deformation of the mean flow in the jet entrance. On the other hand, the term associated with shearing deformation is important for the initiation of PST. Analysis of baroclinic energetics reveals that the intensification of the AST activity in midwinter is mainly attributed to coincidence between location of maximum poleward and upward eddy heat fluxes and that of the largest meridional temperature gradient over slight upstream of the AST. The relatively large amount of precipitable water and meridional eddy moisture flux along baroclinic energy conversion axis likely provides a more favorable environment for baroclinic eddy growth over the North Atlantic than over the North Pacific. In the meantime, the midwinter minimum of the PST activity is attributable to the southward shift of the Pacific jet stream that leads to discrepancy between core region of poleward and upward heat fluxes and that of meridional thermal gradient. Weakening of eddy-mean flow interaction due to eddy shape and reduction of moist effect are also responsible for the weakening of storm track activities in midwinter when the strongest baroclinicity exists over the North Pacific. [ABSTRACT FROM AUTHOR]

Published
2011
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34. A possible mechanism for El Niño-like warming in response to the future greenhouse warming.

Author

Kug, Jong-Seong, Sooraj, K. P., Jin, Fei-Fei, Ham, Yoo-Geun, and Kim, Daehyun

Subjects
EL Nino, GREENHOUSE effect, CLIMATE change, WEATHER forecasting, CLIMATOLOGY
Abstract

Using the climate change experiments generated for the Fourth Assessment of the Intergovernmental Panel on Climate Change, a possible mechanism for the El Niño-like warming in response to the greenhouse warming is suggested. From the coupled global climate model (CGCM) simulations with climate change scenario, it is found that the Bjerknes air-sea coupled process is a dominant contributor to the tropical Pacific response. However, it is revealed that most CGCMs commonly simulate the off-equatorial maximum of precipitation change. It is suggested here that the off-equatorial precipitation and the associated equatorial westerlies play a seeding role in triggering an El Niño-like warming response. Atmospheric GCM (AGCM) experiments show that even uniform sea-surface temperature (SST) warming leads to off-equatorial increase in precipitation which brings equatorial westerlies, implying that these non-uniform (off-equatorial) responses can play a seeding role for the El Niño-like warming pattern. Copyright © 2010 Royal Meteorological Society [ABSTRACT FROM AUTHOR]

Published
2011
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35. An ENSO stability analysis. Part I: results from a hybrid coupled model.

Author

Kim, Seon and Jin, Fei-Fei

Subjects
*GENERAL circulation model, *CLIMATOLOGY, *ATMOSPHERE, *CLIMATE change, *SOUTHERN oscillation, *SIMULATION methods & models, EL Nino
Abstract

In this study, we use the Bjerknes stability (BJ) index as a tool to investigate overall El Niño-Southern Oscillation (ENSO) stability in a hybrid-coupled model (HCM) with various atmosphere and ocean background states. This HCM shows that ENSO growth rates as measured by the BJ index and linear growth rates estimated directly with a time series of the Niño 3.4 indices from the coupled model simulations exhibit similar dependence on background states, coupling strength, and thermodynamic damping intensity. That is, the BJ index and linear growth rates increase with a decrease in the intensity of the background wind, an increase in coupling strength, or a decrease in the intensity of thermodynamic damping, although the BJ index tends to overestimate the growth rate. A detailed analysis of the components of the BJ index formula suggests the importance of model climatological background states and oceanic dynamic parameters in determining ENSO stability. We conclude that the BJ index may serve as a useful tool for qualitatively evaluating the overall ENSO stability in coupled models or in observations without a detailed eigen-analysis that is difficult to perform in models more complex than relatively simple models. [ABSTRACT FROM AUTHOR]

Published
2011
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36. An ENSO stability analysis. Part II: results from the twentieth and twenty-first century simulations of the CMIP3 models.

Author

Kim, Seon and Jin, Fei-Fei

Subjects
*CIRCULATION models, *GLOBAL warming, *SIMULATION methods & models, *SOUTHERN oscillation, *CLIMATE change, *GLOBAL temperature changes, EL Nino
Abstract

In this study, a Bjerknes stability (BJ) index, proposed by Jin et al. (), is adopted to assess the overall stability of El Niño and Southern Oscillation (ENSO) in state-of-the-art coupled models. The twentieth and twenty-first century simulations of 12 coupled models among the coupled model intercomparison project phase 3 models used in the intergovernmental panel on climate change forth assessment report demonstrate a significant positive correlation between ENSO amplitude and ENSO stability as measured by the BJ index. The simulations also show a diversity of behavior regarding the ENSO stability among the coupled models, which can be attributed to different mean state and sensitivity of an oceanic and atmospheric response to wind and SST forcing from model to model. When respective components of the BJ index obtained from the coupled models are compared with those from observations, it is revealed that most coupled models underestimate the thermodynamic damping effect and the positive effect of the zonal advective and thermocline feedback. Under increased CO induced warm climate, changes, relative to the twentieth century simulations, in the damping and feedback terms responsible for the ENSO stability measured by the BJ index can be linked to mean state changes and associated atmospheric and oceanic response sensitivity changes. There is a clear multi-model trend in the damping terms and positive zonal advective feedback, thermocline feedback, and Ekman feedback terms under enhanced greenhouse gas conditions. However, the various behavior among the coupled models in competition between the positive feedback and negative damping terms in the BJ index formula prevent the formation of a definitive conclusion regarding future projections of ENSO stability using the current coupled models. [ABSTRACT FROM AUTHOR]

Published
2011
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