Sea surface temperature anomaly of Southwest Pacific dipole in boreal Winter–Spring: a mechanism for the Indian Ocean Dipole

The formation mechanisms of the Indian Ocean Dipole (IOD) have been studied extensively. However, few studies have considered the influence of the South Pacific atmosphere and sea surface temperature (SST) variability on IOD formation. In this study, reanalysis data, CMIP6 model outputs, and linear...

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Bibliographic Details
Published inClimate dynamics Vol. 62; no. 3; pp. 1909 - 1923
Main Authors Jiang, Jilan, Xu, Kang, Liu, Yimin, Wang, Weiqiang, Wu, Guoxiong
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.03.2024
Springer Nature B.V
Subjects
Anticyclonic circulation
Climatology
Cooling
Cyclonic circulation
Diabatic heating
Dipoles
Downwelling
Earth and Environmental Science
Earth Sciences
El Nino
El Nino phenomena
Evaporation
Feedback
Geophysics/Geodesy
Kelvin waves
Ocean circulation
Oceanography
Oceans
Original Article
Planetary waves
Positive feedback
Rossby waves
Sea surface
Sea surface temperature
Sea surface temperature anomalies
Spring
Spring (season)
Summer
Surface temperature
Surface wind
Temperature anomalies
Thermocline
Upwelling
Walker circulation
Wind
Winds
Winter
Indian Ocean
Southern Australian anticyclone
El Niño–Southern Oscillation
Indian Ocean Dipole
Southwest Pacific Dipole SSTA
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Summary:The formation mechanisms of the Indian Ocean Dipole (IOD) have been studied extensively. However, few studies have considered the influence of the South Pacific atmosphere and sea surface temperature (SST) variability on IOD formation. In this study, reanalysis data, CMIP6 model outputs, and linear baroclinic model experiments were used to investigate this influence. The results revealed a close connection between the preceding boreal winter–spring Southwest Pacific Dipole (SWPD) SST anomaly (SSTA) pattern and the subsequent IOD and associated physical mechanisms. Facilitated by the local air–sea positive feedback, the positive SWPD, coupled with low-level cyclonic circulations, persists from the preceding winter to early summer. During early summer, the below-normal precipitation and diabatic heating associated with the SWPD western pole cooling strengthens and induces an anticyclonic circulation on its western side as the climatological southeasterly winds encroach northward. This anticyclonic circulation extends from southern Australia into the tropical southeastern Indian Ocean, favoring enhanced southeasterly winds and cooling off Java-Sumatra. Subsequently, the IOD develops in summer–autumn with the aid of wind–evaporation–SST and wind–thermocline–SST positive feedback. The westward downwelling Rossby wave and eastward upwelling Kelvin wave associated with surface wind anomalies also contribute to the IOD western pole warming and eastern pole cooling, respectively. Furthermore, the IOD interacts with El Niño through Walker circulation and increases its amplitude. These findings are supported by the results obtained from the linear baroclinic model and CMIP6 historical simulations and can potentially improve the predictability of the IOD.
ISSN:0930-7575
1432-0894
DOI:10.1007/s00382-023-07002-3