Wonsun Park scite author profile

The Atlantic Ocean receives warm, saline water from the Indo-Pacific Ocean through Agulhas leakage around the southern tip of Africa. Recent findings suggest that Agulhas leakage is a crucial component of the climate system and that ongoing increases in leakage under anthropogenic warming could strengthen the Atlantic overturning circulation at a time when warming and accelerated meltwater input in the North Atlantic is predicted to weaken it. Yet in comparison with processes in the North Atlantic, the overall Agulhas system is largely overlooked as a potential climate trigger or feedback mechanism. Detailed modelling experiments--backed by palaeoceanographic and sustained modern observations--are required to establish firmly the role of the Agulhas system in a warming climate.

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Pacific origin of the abrupt increase in Indian Ocean heat content during the warming hiatus

Lee

et al. 2015

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Indian Ocean hides Global Warming Marine scientists proof additional heat uptake during the past decades May 18, 2015/Miami/Kiel. Why has the global temperature rise paused during the past two decades? A team of scientists from the US and the German GEOMAR Helmholtz Centre for Ocean Research Kiel was able to now show that the heat content of the Indian Ocean has risen substantially since late 1990s although the global temperature showed only little changes.

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North Atlantic Ocean control on surface heat flux on multidecadal timescales

Gulev

Latif

Keenlyside

et al. 2013

Nature

273

234

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Nearly 50 years ago Bjerknes suggested that the character of large-scale air-sea interaction over the mid-latitude North Atlantic Ocean differs with timescales: the atmosphere was thought to drive directly most short-term--interannual--sea surface temperature (SST) variability, and the ocean to contribute significantly to long-term--multidecadal--SST and potentially atmospheric variability. Although the conjecture for short timescales is well accepted, understanding Atlantic multidecadal variability (AMV) of SST remains a challenge as a result of limited ocean observations. AMV is nonetheless of major socio-economic importance because it is linked to important climate phenomena such as Atlantic hurricane activity and Sahel rainfall, and it hinders the detection of anthropogenic signals in the North Atlantic sector. Direct evidence of the oceanic influence of AMV can only be provided by surface heat fluxes, the language of ocean-atmosphere communication. Here we provide observational evidence that in the mid-latitude North Atlantic and on timescales longer than 10 years, surface turbulent heat fluxes are indeed driven by the ocean and may force the atmosphere, whereas on shorter timescales the converse is true, thereby confirming the Bjerknes conjecture. This result, although strongest in boreal winter, is found in all seasons. Our findings suggest that the predictability of mid-latitude North Atlantic air-sea interaction could extend beyond the ocean to the climate of surrounding continents.

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Rising Arctic Ocean temperatures cause gas hydrate destabilization and ocean acidification

Biastoch

Treude

Rüpke

et al. 2011

Geophys. Res. Lett.

281

257

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[1] Vast amounts of methane hydrates are potentially stored in sediments along the continental margins, owing their stability to low temperature -high pressure conditions. Global warming could destabilize these hydrates and cause a release of methane (CH 4 ) into the water column and possibly the atmosphere. Since the Arctic has and will be warmed considerably, Arctic bottom water temperatures and their future evolution projected by a climate model were analyzed. The resulting warming is spatially inhomogeneous, with the strongest impact on shallow regions affected by Atlantic inflow. Within the next 100 years, the warming affects 25% of shallow and mid-depth regions containing methane hydrates. Release of methane from melting hydrates in these areas could enhance ocean acidification and oxygen depletion in the water column. The impact of methane release on global warming, however, would not be significant within the considered time span. Citation: Biastoch, A., et al. (2011), Rising Arctic Ocean temperatures cause gas hydrate destabilization and ocean acidification, Geophys. Res. Lett., 38, L08602,

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Multi-centennial variability controlled by Southern Ocean convection in the Kiel Climate Model

2012

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Wonsun Park

On the role of the Agulhas system in ocean circulation and climate

Pacific origin of the abrupt increase in Indian Ocean heat content during the warming hiatus

North Atlantic Ocean control on surface heat flux on multidecadal timescales

Rising Arctic Ocean temperatures cause gas hydrate destabilization and ocean acidification

Multi-centennial variability controlled by Southern Ocean convection in the Kiel Climate Model

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