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1. Holocene hydroclimatic variability in the tropical Pacific explained by changing ENSO diversity

   https://doi.org/10.1038/s41467-022-34880-8  

   Karamperidou, Christina; DiNezio, Pedro N. (December 2022, Nature Communications)

   Abstract Understanding El Niño-Southern Oscillation (ENSO) response to past climate forcings is hindered by conflicting paleoclimate evidence. Records from the eastern Pacific show an intensification of ENSO variability from early to late Holocene, while records from the central Pacific show highly variable ENSO throughout the Holocene without an obvious relation to insolation forcing, which is the main climate driver during this interval. Here, we show via climate model simulations that conflicting Holocene records can be reconciled by considering changes in the relative frequency of the three preferred spatial patterns in which El Niño events occur (Eastern Pacific, Central Pacific, and Coastal) and in the strength of their hydroclimatic impacts. The relationship between ENSO diversity and variance is not only crucial for interpreting paleo-ENSO records and understanding ENSO response to external forcings but can also be used across climate model simulations to help evaluate the realism of ENSO projections in a changing climate. 

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2. An Inconsistent ENSO Response to Northern Hemisphere Stadials Over the Last Deglaciation

   https://doi.org/10.1029/2023gl107634  

   Glaubke, Ryan H; Schmidt, Matthew W; Hertzberg, Jennifer E; Ward, Lenzie G; Marcantonio, Franco; Schimmenti, Danielle; Thirumalai, Kaustubh (June 2024, Geophysical Research Letters)

   Abstract The dynamics shaping the El Niño‐Southern Oscillation's (ENSO) response to present and future climate change remain unclear, partly due to limited paleo‐ENSO records spanning past abrupt climate events. Here, we measure Mg/Ca ratios on individual foraminifera to reconstruct east Pacific subsurface temperature variability, a proxy for ENSO variability, across the last 25,000 years, including the millennial‐scale events of the last deglaciation. Combining these data with proxy system model output reveals divergent ENSO responses to Northern Hemisphere stadials: enhanced variability during Heinrich Stadial 1 (H1) and reduced variability during the Younger Dryas (YD), relative to the Holocene. H1 ENSO likely intensified through meltwater‐induced changes to ocean/atmospheric circulation, a response observed in models, but the lack of a similar response during the YD challenges model simulations. We suggest the tropical Pacific mean state during H1 primed ENSO for larger fluctuations under meltwater forcing, whereas the YD mean state likely buffered against it. 

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3. Modulation of late Pleistocene ENSO strength by the tropical Pacific thermocline

   https://doi.org/10.1038/s41467-020-19161-6  

   Rustic, Gerald T; Polissar, Pratigya J; Ravelo, Ana Christina; White, Sarah M (December 2020, Natural computing series)

   Abstract The El Niño Southern Oscillation (ENSO) is highly dependent on coupled atmosphere-ocean interactions and feedbacks, suggesting a tight relationship between ENSO strength and background climate conditions. However, the extent to which background climate state determines ENSO behavior remains in question. Here we present reconstructions of total variability and El Niño amplitude from individual foraminifera distributions at discrete time intervals over the past ~285,000 years across varying atmospheric CO₂levels, global ice volume and sea level, and orbital insolation forcing. Our results show a strong correlation between eastern tropical Pacific Ocean mixed-layer thickness and both El Niño amplitude and central Pacific variability. This ENSO-thermocline relationship implicates upwelling feedbacks as the major factor controlling ENSO strength on millennial time scales. The primacy of the upwelling feedback in shaping ENSO behavior across many different background states suggests accurate quantification and modeling of this feedback is essential for predicting ENSO’s behavior under future climate conditions. 

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4. The frequency and intensity of El Niño events reconstructed from 3 independent sedimentary sequences

   Mark, S; Shelef, E; Rodbell, D T; Abbott, MB; Moy, CM (December 2023, American Geophysical Union)

   Continuous archives of the El Niño Southern Oscillation (ENSO) spanning multiple millennia are rare, as few geologic records faithfully preserve evidence of sub-decadal climate variability over long timescales. Different proxy archive types –such as lake sediments, foraminifera, tree-rings, and corals—have their own unique sensitivities to the climate system and can thus be difficult to intercompare. The sedimentary sequence from Laguna Pallcacocha, Ecuador, represents one of the most widely cited Holocene-scale ENSO reconstructions. Hundreds of mineral-rich flood laminae result from eastern Pacific El Niño events, when convective rainstorms drive erosion and terrigenous sediment transport in the Laguna Pallcacocha watershed. This reconstruction, however, is tangibly different from other ENSO proxy records as well as flood stratigraphies from proximal lakes. The watersheds of these nearby lakes have markedly different landscape characteristics, suggesting that the intensity of storms which generate flood deposits differ between each watershed. Thus, an integrated analysis of these three separate records helps constrain the frequency of paleo-ENSO events of different magnitudes. While moderate El Niño events may have been most frequent approximately 1000 years BP, particularly intense El Niño’s occur more frequently during the subsequent Little Ice Age (1450-1850 CE), consistent with tree-ring based reconstructions of ENSO amplitude and foraminiferal records of high-intensity eastern Pacific warming. A widely reported minima in El Niño frequency between approximately 7-4 kyr BP is a prominent feature in Laguna Pallcacocha record. This minima is not present, however, in the high-intensity flood stratigraphies from the other two lakes, which align more closely with ENSO amplitude records derived from speleothems and corals. These findings highlight the value of integrating evidence from multiple paleoclimate archives in ENSO reconstructions. 

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5. The Tropical Pacific Annual Cycle and ENSO in PMIP4 Simulations of the Mid‐Holocene

   https://doi.org/10.1029/2021JC017587  

   Zhang, Xiaolin; Atwood, Alyssa R.; Nag, Bappaditya; Cobb, Kim M. (August 2022, Journal of Geophysical Research: Oceans)

   We investigate the tropical Pacific annual cycle and the El Niño/Southern Oscillation (ENSO) in four mid‐Holocene simulations. Our results show that both ENSO variability and the amplitude of the annual cycle of the tropical Pacific cold tongue are reduced under mid‐Holocene forcing, along with a modified annual cycle in ENSO variance. The weakened annual cycle of the cold tongue is attributed to an ocean dynamical response to westerly wind anomalies in the western equatorial Pacific in boreal spring in addition to a thermodynamic response to local insolation changes in the eastern Pacific. The anomalous westerly winds in boreal spring excite an annual downwelling Kelvin wave that deepens the thermocline and propagates eastward along the equator, reaching the central and eastern equatorial Pacific during the development season of ENSO in boreal summer. Upon reaching the eastern Pacific, the downwelling Kelvin wave deepens the near‐surface thermocline, warming the surface ocean and weakening the local ocean‐atmosphere coupling critical to the growth of ENSO events. The westerly wind anomaly is associated with a shift in convection in the western Pacific driven by greater cooling of the Maritime Continent than western Pacific Ocean during the first half of the year (January to June) under tropical insolation forcing. By elucidating a common set of mechanisms responsible for a reduced cold tongue annual cycle and ENSO variability in a diverse range of mid‐Holocene simulations, this work yields important insight into the linkages between the tropical Pacific annual cycle and ENSO that are critical for understanding tropical Pacific climate variability. 

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