Mid‐latitude leading double‐dip La Niña

Understanding the evolution asymmetry between El Niño and La Niña events is challenging. Unlike El Niño, most La Niña events are characterised by a double‐dip cooling (a.k.a. multi‐year La Niña). Herein, we examined how single‐ and multi‐year La Niña events differ by analysing observational and clim...

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Veröffentlicht in:	International journal of climatology 2021-01, Vol.41 (S1), p.E1353-E1370
Hauptverfasser:	Park, Jae‐Heung, An, Soon‐Il, Kug, Jong‐Seong, Yang, Young‐Min, Li, Tim, Jo, Hyun‐Su
Format:	Artikel
Sprache:	eng
Schlagworte:	Atmospheric circulation Climate models Climatic analysis Cooling Cyclonic circulation double‐dip La Niña El Nino El Nino phenomena La Nina La Nina events Meteorological satellites multi‐year La Niña Oceans Pacific meridional mode Recharging single‐year La Niña Surface cooling Sverdrup transport Tropical environments
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container_title	International journal of climatology
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creator	Park, Jae‐Heung An, Soon‐Il Kug, Jong‐Seong Yang, Young‐Min Li, Tim Jo, Hyun‐Su
description	Understanding the evolution asymmetry between El Niño and La Niña events is challenging. Unlike El Niño, most La Niña events are characterised by a double‐dip cooling (a.k.a. multi‐year La Niña). Herein, we examined how single‐ and multi‐year La Niña events differ by analysing observational and climate‐model data sets. Single‐year La Niña events tend to develop narrowly within the tropics from a central Pacific‐type El Niño (Niño‐4 > Niño‐3), whereas multi‐year La Niña events tend to originate from an eastern Pacific‐type El Niño (Niño‐3 > Niño‐4) and are well‐connected to mid‐latitudes through the Pacific meridional mode, which leads to a meridionally wider response of the off‐equatorial low‐level atmospheric anti‐cyclonic circulation. As the anti‐cyclonic circulation controls the amount of equatorial upper‐ocean heat recharge through Sverdrup transport, for single‐year La Niña, efficient ocean recharging due to a narrower anti‐cyclonic circulation causes a fast transition to an El Niño or a fast termination of a La Niña. In contrast, for multi‐year La Niña, a weaker recharging causes surface cooling to persist, leading to another La Niña in the following year. Time‐longitude graphs of equatorial SSTA (shading), anomalous zonal wind‐stress (vectors, black: Zonal wind‐stress >0.25 and blue: Zonal wind‐stress < −0.25, unit: 102 × N⋅m–2), and anomalous wind‐stress curl (contour, N⋅m–3 × 108) over the north off‐equator (0–15°N) for (a) single‐year La Niña events and (b) multi‐year La Niña events.
doi_str_mv	10.1002/joc.6772
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Unlike El Niño, most La Niña events are characterised by a double‐dip cooling (a.k.a. multi‐year La Niña). Herein, we examined how single‐ and multi‐year La Niña events differ by analysing observational and climate‐model data sets. Single‐year La Niña events tend to develop narrowly within the tropics from a central Pacific‐type El Niño (Niño‐4 > Niño‐3), whereas multi‐year La Niña events tend to originate from an eastern Pacific‐type El Niño (Niño‐3 > Niño‐4) and are well‐connected to mid‐latitudes through the Pacific meridional mode, which leads to a meridionally wider response of the off‐equatorial low‐level atmospheric anti‐cyclonic circulation. As the anti‐cyclonic circulation controls the amount of equatorial upper‐ocean heat recharge through Sverdrup transport, for single‐year La Niña, efficient ocean recharging due to a narrower anti‐cyclonic circulation causes a fast transition to an El Niño or a fast termination of a La Niña. 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subjects	Atmospheric circulation Climate models Climatic analysis Cooling Cyclonic circulation double‐dip La Niña El Nino El Nino phenomena La Nina La Nina events Meteorological satellites multi‐year La Niña Oceans Pacific meridional mode Recharging single‐year La Niña Surface cooling Sverdrup transport Tropical environments
title	Mid‐latitude leading double‐dip La Niña
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