An Episodic Weakening in the Boreal Spring SST–Precipitation Relationship in the Western Tropical Pacific since the Late 1990s

Abstract We found that a positive sea surface temperature (SST)–precipitation relationship in the western tropical Pacific (WTP) during boreal spring, in which higher SSTs are associated with higher precipitation, episodically weakens from the late 1990s to the early 2010s. During 1980–98, warm SSTs induce positive precipitation and low pressure in the WTP. The associated enhanced convection dampens the initial warm SSTs by reflecting incoming solar radiation. The reduced incoming solar radiation into the ocean leads to a SST cooling tendency. In contrast, the associated southwesterly wind anomalies reduce oceanic mixing by decreasing the mean wind, contributing to an SST warming tendency, though relatively small. Therefore, the cloud–radiation effect is a dominant process of the negative SST tendency. By contrast, during 1999–2014, although an SST cooling tendency is similarly induced by warm SST anomalies, the cooling tendency is enhanced by anomalous ocean advection, as a result of enhanced easterly wind anomalies in the southern part of the WTP. This results in a weakening of a positive relationship of the SST and precipitation during 1999–2014. As such, the associated anomalous convective heating in the WTP during 1999–2014 is weak, changing the atmospheric teleconnection patterns in the midlatitude and surface air temperature anomalies in western North America and northeastern Eurasia.

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Inter-basin and Multi-time Scale Interactions in generating the 2019 Extreme Indian Ocean Dipole

Journal of Climate ◽

10.1175/jcli-d-20-0760.1 ◽

2021 ◽

pp. 1-39

Author(s):

Lei Zhang ◽

Weiqing Han ◽

Zeng-Zhen Hu

Keyword(s):

Indian Ocean ◽

Indian Ocean Dipole ◽

Intraseasonal Oscillation ◽

Tropical Indian Ocean ◽

Forecast Model ◽

Tropical Pacific ◽

Boreal Summer ◽

Indian Ocean Dipole Event ◽

Easterly Wind ◽

Western Tropical Pacific

AbstractAn unprecedented extreme positive Indian Ocean Dipole event (pIOD) occurred in 2019, which has caused widespread disastrous impacts on countries bordering the Indian Ocean, including the East African floods and vast bushfires in Australia. Here we investigate the causes for the 2019 pIOD by analyzing multiple observational datasets and performing numerical model experiments. We find that the 2019 pIOD is triggered in May by easterly wind bursts over the tropical Indian Ocean associated with the dry phase of the boreal summer intraseasonal oscillation, and sustained by the local atmosphere-ocean interaction thereafter. During September-November, warm sea surface temperature anomalies (SSTA) in the central-western tropical Pacific further enhance the Indian Ocean’s easterly winds, bringing the pIOD to an extreme magnitude. The central-western tropical Pacific warm SSTA is strengthened by two consecutive Madden Julian Oscillation (MJO) events that originate from the tropical Indian Ocean. Our results highlight the important roles of cross-basin and cross-timescale interactions in generating extreme IOD events. The lack of accurate representation of these interactions may be the root for a short lead time in predicting this extreme pIOD with a state-of-the-art climate forecast model.

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Effect of Tropical Waves on the Tropical Tropopause Transition Layer Upwelling

Journal of the Atmospheric Sciences ◽

10.1175/2010jas3434.1 ◽

2010 ◽

Vol 67 (10) ◽

pp. 3130-3148 ◽

Cited By ~ 24

Author(s):

Jung-Hee Ryu ◽

Sukyoung Lee

Keyword(s):

Rossby Wave ◽

Transition Layer ◽

Tropical Pacific ◽

Kelvin Waves ◽

Cold Trap ◽

Source Analysis ◽

Convective Heating ◽

Background Flow ◽

Western Tropical Pacific ◽

Tropical Waves

Abstract An initial-value problem is employed with a GCM to investigate the role of the convectively driven Rossby and Kelvin waves for tropopause transition layer (TTL) upwelling in the tropics. The convective heating is mimicked with a prescribed heating field, and the Lagrangian upwelling is identified by examining the evolution of passive tracer fields whose initial distribution is identical to the initial heating field. This study shows that an overturning circulation, induced by the tropical Rossby waves, is capable of generating the TTL upwelling. Even when the heating is placed in the eastern Pacific, the TTL upwelling occurs only over the western tropical Pacific, indicating that the background flow plays a crucial role. The results from a Rossby wave source analysis suggest that a key feature of the background flow is the strong absolute vorticity gradient associated with the Asian subtropical jet. In addition, static stability is relatively weak over the western Pacific, suggesting that this may also contribute to the TTL upwelling in that region. The background flow also modulates the internal Kelvin waves in such a manner that the coldest region in the TTL (resembling the observed “cold trap”) occurs over the western tropical Pacific. As a consequence, the upwelling air, induced by the meridional momentum flux of the Rossby wave, passes through the cold trap generated by the Kelvin wave. Since in reality the background flow is shaped by the convective heating, the climatological western tropical Pacific heating is ultimately responsible for both the TTL upwelling and the cold trap; however, both processes are realized indirectly through its impact on the background flow and the generation of the tropical waves.

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Incoming Solar Radiation over the Tropical Pacific

Nature ◽

10.1038/217149a0 ◽

1968 ◽

Vol 217 (5124) ◽

pp. 149-150 ◽

Cited By ~ 3

Author(s):

W. H. QUINN ◽

W. V. BURT

Keyword(s):

Solar Radiation ◽

Tropical Pacific ◽

Incoming Solar Radiation ◽

The Tropical Pacific

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Coupled Ocean–Atmosphere Response to Idealized Freshwater Forcing over the Western Tropical Pacific

Journal of Climate ◽

10.1175/2009jcli3009.1 ◽

2010 ◽

Vol 23 (7) ◽

pp. 1945-1954 ◽

Cited By ~ 11

Author(s):

Lixin Wu ◽

Yan Sun ◽

Jiaxu Zhang ◽

Liping Zhang ◽

Shoshiro Minobe

Keyword(s):

Climate Model ◽

Tropical Pacific ◽

Meridional Overturning Circulation ◽

Bjerknes Feedback ◽

Atmospheric Teleconnection ◽

Western Tropical Pacific ◽

Freshwater Forcing ◽

The Pacific ◽

Ocean Atmosphere ◽

The Tropics

Abstract The coupled ocean–atmosphere responses to idealized freshwater forcing in the western tropical Pacific are studied using a fully coupled climate model. The model explicitly demonstrates that freshwater forcing in the western tropical Pacific can lead to a basinwide response with the pattern resembling the Pacific decadal oscillation. In the tropics, a negative (positive) freshwater forcing over the western tropical Pacific decreases (increases) sea surface height locally, and sets up a positive (negative) zonal pressure gradient anomaly, which accelerates (decelerates) the meridional overturning circulation and equatorial surface westward flow. This leads to an intensification (reduction) of meridional heat divergence and vertical cold advection, and thus a development of La Niña (El Niño)–like responses in the tropics. The tropical responses are further substantiated by the positive Bjerknes feedback, and subsequently force significant changes in the extratropical North Pacific through atmospheric teleconnection. The local freshwater response also reinforces the imposed forcing, forming a positive feedback loop. Applications to Pacific climate changes are discussed.

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Attribution of the seasonality of atmospheric heating changes over the western tropical Pacific with a focus on the spring season

Climate Dynamics ◽

10.1007/s00382-021-06020-3 ◽

2021 ◽

Author(s):

Shuheng Lin ◽

Song Yang ◽

Shan He ◽

Zhenning Li ◽

Jiaxin Chen ◽

...

Keyword(s):

Diabatic Heating ◽

Global Climate ◽

Deep Convection ◽

Tropical Indian Ocean ◽

Reanalysis Data ◽

The Other ◽

Convective Heating ◽

Easterly Wind ◽

Boreal Spring ◽

The Tropics

AbstractAtmospheric diabatic heating, a major driving force of atmospheric circulation over the tropics, is strongly confined to the tropical western North Pacific (TWNP) region, with the global warmest sea surface temperature (SST). The changes in diabatic heating over the TWNP, which exert great impacts on the global climate system, have recently exhibited a noticeable seasonal dependence with a remarkable increase in boreal spring. In this study, we applied observations, reanalysis data, and numerical experiments to investigate the causes of the seasonality in heating changes. Results show that in boreal spring convection is more sensitive to the TWNP SST, leading to a more significant enhancement of deep convection, although the increase in the SST is nearly the same as that in the other seasons. In the non-spring seasons, the enhanced convection due to increased local SST is suppressed by the anomalous anticyclonic wind shear over the TWNP, generated by the easterly wind anomalies induced by the tropical Indian Ocean (TIO) warming via the Kevin waves. However, the TIO warming does not show any suppressing effect in spring because it is much weaker than that in the other seasons and thus the warming itself cannot induce sufficient convective heating anomalies to excite the Kelvin waves.

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