A Satellite Era Warming Hole in the Equatorial Atlantic Ocean

Nnamchi, Hyacinth C.; Latif, Mojib; Keenlyside, Noel; Park, Wonsun

doi:10.1029/2019jc015834

Cited by 12 publications

(6 citation statements)

References 91 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, multidecadal variability is large. Nnamchi et al (2020) found that SSTs during the satellite era 1979-2018 exhibit a warming hole over the equatorial Atlantic cold tongue region in boreal summer. This lack of surface warming denotes an 11% amplification of the mean SST annual cycle in that region.…”

Section: Introductionmentioning

confidence: 99%

Origin of Weakened Interannual Sea Surface Temperature Variability in the Southeastern Tropical Atlantic Ocean

Prigent

Koungue

Lübbecke

et al. 2020

Geophysical Research Letters

Self Cite

View full text Add to dashboard Cite

Observations and reanalysis products are used to investigate the substantial weakening in the southeastern tropical Atlantic sea surface temperature (SST) variability since 2000. Relative to 1982-1999, the March-April-May SST variability in the Angola-Benguela area (ABA) has decreased by more than 30%. Both equatorial remote forcing and local forcing are known to play an important role in driving SST variability in the ABA. Compared to 1982-1999, since 2000, equatorial remote forcing had less influence on ABA SSTs, whereas local forcing has become more important. In particular, the robust correlation that existed between the equatorial zonal wind stress and the ABA SSTs has substantially weakened, suggesting less influence of Kelvin waves on ABA SSTs. Moreover, the strong correlation linking the South Atlantic Anticyclone and the ABA SSTs has reduced. Finally, multidecadal surface warming of the ABA could also have played a role in the weakening of the interannual SST variability. Plain Language Summary Every few years, the southeastern tropical Atlantic Ocean experiences anomalous sea temperatures that affect fisheries and rainfall. Using observations and reanalysis data, we quantify the Angola-Benguela area (ABA) sea surface temperature (SST) variability during the last decades. Relative to 1982-1999, the March-April-May SST variability in the ABA has decreased by more than 30% since 2000. Remote equatorial forcing through equatorially and coastally trapped oceanic waves and variations in the local winds are the main drivers of ABA SST variability. Since 2000, we find that ABA SSTs are less connected to equatorial winds and exhibit a weaker link with the South Atlantic Anticyclone. Finally, the surface warming of the ABA observed during the post-2000 period also could have played a role in the weakening interannual SST variability.

show abstract

Section: Introductionmentioning

confidence: 99%

Origin of Weakened Interannual Sea Surface Temperature Variability in the Southeastern Tropical Atlantic Ocean

Prigent

Koungue

Lübbecke

et al. 2020

Geophysical Research Letters

Self Cite

View full text Add to dashboard Cite

show abstract

“…As mentioned above (Sect. 1), WEA wind changes could affect the D20 through equatorial waves and lead to SST changes in the EACT region (Planton et al 2018;Marin et al 2009;Nnamchi et al 2020). Under RCP8.5, we analyze the correlation between wind changes in the WEA and D20 changes and found that there is a weak correlation (r = 0.38 not significantly at the 95% significance level) between these two terms (Fig.…”

Section: Changes In the Sst Of Eact And Their Driversmentioning

confidence: 99%

“…An intensification of winds in the WEA could induce upwelling Kelvin waves that propagate eastward and trigger the rising of the thermocline (represented by the 20 °C isotherm or D20) to the East, and vice versa for a weakening of winds (e.g., Castaño-Tierno et al 2018). This movement of the thermocline leads to a reduction (augmentation) in the sea surface height (SSH) and SST in the EACT region (Planton et al 2018;Marin et al 2009;Nnamchi et al 2020). Thus, as the EACT region is largely related to the West African summer monsoon precipitation which is of key importance for agriculture productivity and water availability, it is essential to study the changes of SST under GLENS in this region.…”

Section: Introductionmentioning

confidence: 99%

Response of the Equatorial Atlantic Cold Tongue to Stratospheric Aerosol Geoengineering

Pomalegni¹,

Da‐Allada

Sohou³

et al. 2022

Aerosol Sci Eng

View full text Add to dashboard Cite

By increasing Earth-atmosphere system albedo, Stratospheric Aerosol Geoengineering (SAG) using sulfur dioxide is an artificial potential means, with the goal to mitigate the global warming effects. In this study, we used the simulations from Geoengineering Large Ensemble project realized under the climate change scenario of Representative Concentration Pathway 8.5 (RCP8.5), to investigate the potential impact of SAG on the Sea Surface Temperature (SST) in Equatorial Atlantic Cold Tongue (EACT) and the physical processes driving these changes. Results reveal that in the EACT region, under RCP8.5, SST warms significantly (compared to present‐day climate) with a maximum of 1.7 °C in July, and this increase in SST is mainly due to the local processes related to the weakening of vertical mixing at the base of the mixed layer. This reduction of the vertical mixing is associated to the diminution of the vertical shear from July to April and to the increase of ocean stratification from May to June. However, under SAG, SST decreases significantly throughout the year (compared to present‐day climate) with a maximum cooling of − 0.4 °C in the cold tongue period (May–June). This SST cooling is mainly associated with the non-local processes related to intensification of the westerly equatorial Atlantic wind stress. Finally, results show that the use of SAG to offset all global warming under RCP8.5 results in a slight over compensation of SST in the EACT region.

show abstract

“…These processes can also affect the interannual variability (Prodhomme et al, 2019) and affect the uncertainty of the simulated climate change signal (Tokinaga and Xie, 2011;Nnamchi et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Impact of model’s resolution on the sea surface temperature climate change signal in the South Eastern Tropical Atlantic

Cabos,

Vázquez,

Vara

et al. 2023

Preprint

View full text Add to dashboard Cite

In this paper we study the influence of atmospheric and oceanic resolutions on the sea surface temperature (SST) under climate change and the related mechanisms. To this end, a set of historical period and future simulations in which two different atmospheric resolutions are combined with two different oceanic resolutions, one of them eddy-permitting, are used. We found that the magnitude of the warming is more dependent on atmospheric resolution, while the influence of oceanic resolution is stronger on the spatial pattern of SST changes, leading to the enhancement of the climate change signal in coastal regions. The mechanisms related to these changes involve both the atmosphere and the ocean, with the last playing the main role. We found that changes in upwelling are the primary drivers of SST changes in regions close to the coast, and these changes in SST exhibit a clear seasonal pattern, precisely associated with the significant seasonality of the Benguela upwelling. The radiative and turbulent fluxes are modified by the changes in the climate and are also influenced by the resolution and SST patterns. The net long wave fluxes into the ocean are increased, when the short wave fluxes decrease. These changes result from the adjustment to the increase of greenhouse gasses, which leads to a stronger warming of the atmosphere than the ocean surface, which increases the long wave radiation and the formation of low clouds.

show abstract

A Satellite Era Warming Hole in the Equatorial Atlantic Ocean

Cited by 12 publications

References 91 publications

Origin of Weakened Interannual Sea Surface Temperature Variability in the Southeastern Tropical Atlantic Ocean

Origin of Weakened Interannual Sea Surface Temperature Variability in the Southeastern Tropical Atlantic Ocean

Response of the Equatorial Atlantic Cold Tongue to Stratospheric Aerosol Geoengineering

Impact of model’s resolution on the sea surface temperature climate change signal in the South Eastern Tropical Atlantic

Contact Info

Product

Resources

About