Multidecadal poleward shift of the southern boundary of the Antarctic Circumpolar Current off East Antarctica

Yamazaki, Kenta; Aoki, Shigeru; Katsumata, Katsuro; Hirano, Daisuke; Nakayama, Yoshihiro

doi:10.1126/sciadv.abf8755

Cited by 38 publications

(39 citation statements)

References 46 publications

(130 reference statements)

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“…2a). This temperature change is broadly in line with those estimated previously in the same region 7,15,16 and, remarkably, it is concurrent to an even more pronounced warming of 0.8-2ºC (or 0.1-0.4ºC per decade) over the continental slope (Fig. 1).…”

Section: Deep Warming Off East Antarcticasupporting

confidence: 91%

“…Our focus on the Indian Ocean sector stems from this region's glaciers contributing the bulk of East Antarctic ice-mass loss in recent decades 9,17,18 . Our evaluation of long-term water-mass variability off East Antarctica presents two important advances relative to previous studies 15,16 , in that our dataset: (i) has a substantially improved spatial coverage of the seasonally ice-covered areas near the East Antarctic margins, particularly over the continental slope and shelves; and (ii) spans a longer (by several decades) period.…”

Section: Deep Warming Off East Antarcticamentioning

confidence: 99%

“…While investigations of the interdecadal evolution of CDW temperature reveal a widespread, persistent warming to the north of and within the ACC, equatorward of ~60ºS 7,13,14 , there has been little indication of robust long-term temperature changes further to the south. Only recently, two studies 15,16 have put forward the suggestion that a CDW warming might be underway poleward of ~60ºS, possibly linked to a southward shift of the ACC's southern boundary in the eastern Indian region (115-150ºE) 15 or a CDW shoaling south of Tasmania 16 . However, spatio-temporal sampling limitations prevented these works from assessing the generality of CDW warming across the Indian Ocean sector of East Antarctica and, crucially, whether such warming (i) extends all the way to the continental slope, the access point of CDW to the East Antarctic shelves, and (ii) reaches the East Antarctic Ice Sheet.…”

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confidence: 99%

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Poleward shift of Circumpolar Deep Water threatens the East Antarctic Ice Sheet

Herráiz‐Borreguero

Garabato

2022

Nat. Clim. Chang.

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Future sea-level rise (SLR) projections carry large uncertainties, mainly driven by the unknown response of the Antarctic Ice Sheet to climate change. During the past four decades, the contribution of the East Antarctic Ice Sheet to SLR has increased. However, unlike for West Antarctica, the causes of East Antarctic ice-mass loss remain largely unexplored. Here, using oceanographic observations off East Antarctica (80º-160ºE) we show that mid-depth Circumpolar Deep Water has warmed by 0.8-2.0°C along the continental slope between 1930-1990 and 2010-2018. Our results indicate that this warming may be implicated in East Antarctic ice-mass loss and coastal water-mass reorganisation. Further, it is associated with an interdecadal, summer-focused poleward shift of the westerlies over the Southern Ocean. As this shift is predicted to persist into the 21st century, the oceanic heat supply to East Antarctica may continue to intensify, threatening the ice sheet's future stability. Main textThe Antarctic Ice Sheet has been losing mass at an accelerated rate since the 1970s 1 , and now accounts for ~15% of global SLR 5 . In West Antarctica, the ice-mass loss has been attributed to a wind-driven increase in the transfer of warm CDW toward the floating ice shelves 2,3 . As the ice shelves melt, their mechanical buttressing of tributary glaciers is reduced, leading to faster glacier flow toward the coast and greater freshwater input to the ocean 6 . Consistent with this view, observed interdecadal trends in West Antarctic ice-mass loss have been linked to warming of the continental shelf's deeper oceanic layers, with either the evolving decadalmean temperature 7 or amplitude of interannual temperature variability 2,8 posited to exert the key melting-controlling role. A singular feature of West Antarctic change is that the measured ocean warming occurs on the continental shelf 2 , rather than in the Antarctic Circumpolar Current (ACC) offshore 2 , pointing to a perturbed rate of CDW transport across the shelf break as the warming's underpinning factor.The ice-mass loss in East Antarctica is dominated by changes in the Wilkes Basin 9 (100º-142ºE), in the eastern Indian Ocean sector. Its causes remain both undetermined and little probed. The presence of modified CDW in proximity to several ice shelves 10,11,12 hints at an increased delivery of heat from the ACC plausibly being implicated in regional ice-mass loss. However, evidence of such an increase, and knowledge of its possible forcings, are currently scarce. While investigations of the interdecadal evolution of CDW temperature reveal a widespread, persistent warming to the north of and within the ACC, equatorward of ~60ºS 7,13,14 , there has been little indication of robust long-term temperature changes further to the south. Only recently, two studies 15,16 have put forward the suggestion that a CDW warming might be underway poleward of ~60ºS, possibly linked to a southward shift of the ACC's southern boundary in the eastern Indian region (115-150ºE) 15 or a CDW shoaling so...

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Section: Deep Warming Off East Antarcticasupporting

confidence: 91%

Section: Deep Warming Off East Antarcticamentioning

confidence: 99%

mentioning

confidence: 99%

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Poleward shift of Circumpolar Deep Water threatens the East Antarctic Ice Sheet

Herráiz‐Borreguero

Garabato

2022

Nat. Clim. Chang.

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“…One of the factors that may cause variations of xCO 2 sea is the spatial distribution of front positions. The discovery by Yamazaki et al (2021) that the Southern Boundary (SB) of Antarctic Circumpolar Current (ACC) moved southward during the period between BROKE and this study indicates that the upwelling region of Circumpolar Deep Water (CDW) moved southward. As a result, the maximum concentration of nitrate near the TML increased, and the difference in nitrate concentrations between the ocean surface and the TML increased (Figure 13).…”

Section: Decadal Trendmentioning

confidence: 68%

“…Significant changes have taken place in the marine environment of the Indian sector during the two decades since the BROKE study (Auger et al, 2021). For example, Yamazaki et al (2021) have shown that the Southern Boundary (SB) of the Antarctic Circumpolar Current (ACC) moved southward from 1996 to 2019. This caused changes in the distribution of nutrients and might influence the seasonal variability of pCO 2 .…”

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confidence: 99%

Seasonal Variations and Drivers of Surface Ocean pCO₂ in the Seasonal Ice Zone of the Eastern Indian Sector, Southern Ocean

et al. 2021

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To quantitatively assess the inorganic carbon cycle in the eastern Indian sector of the Southern Ocean (80–150°E, south of 60°S), we measured ocean surface temperature, salinity, total alkalinity (TA), the partial pressure of carbon dioxide (pCO2), and concentrations of chlorophyll‐a (chl a), dissolved inorganic carbon (DIC), and nutrients during the KY18 survey (December 2018–January 2019). The sea–air CO2 flux in this region was −8.3 ± 12.7 mmol m−2 day−1 (−92.1 to +10.6 mmol m−2 day−1). The ocean was therefore a weak CO2 sink. Based on the DIC and TA in the temperature minimum layer, we estimated the change of pCO2 from winter to summer (δpCO2) due to changes in water temperature, salinity, and biological activity (photosynthesis). The spatial distribution of pCO2 in the western part (80–110°E) of the study area was mainly driven by biological activity, which decreased pCO2 from December to early January, and in the eastern part (110–150°E) by temperature, which increased pCO2 from January to February. We also examined the changes in the CO2 concentrations (xCO2) over time by comparing data from 1996 with our data (2018–2019). The oceanic and atmospheric xCO2 increased by 23 and 45 ppm in 23 years, respectively. These changes of ocean xCO2 were mainly driven by an increase in CO2 uptake from the atmosphere as a result of the rise in atmospheric xCO2 and increase in biological activity associated with the change in the water‐mass distribution.

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Onshore Diffusion of Circumpolar Deep Water

Yamazaki

Aoki

Mizobata

2022

Preprint

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Multidecadal poleward shift of the southern boundary of the Antarctic Circumpolar Current off East Antarctica

Cited by 38 publications

References 46 publications

Poleward shift of Circumpolar Deep Water threatens the East Antarctic Ice Sheet

Poleward shift of Circumpolar Deep Water threatens the East Antarctic Ice Sheet

Seasonal Variations and Drivers of Surface Ocean pCO₂ in the Seasonal Ice Zone of the Eastern Indian Sector, Southern Ocean

Onshore Diffusion of Circumpolar Deep Water

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Multidecadal poleward shift of the southern boundary of the Antarctic Circumpolar Current off East Antarctica

Cited by 38 publications

References 46 publications

Poleward shift of Circumpolar Deep Water threatens the East Antarctic Ice Sheet

Poleward shift of Circumpolar Deep Water threatens the East Antarctic Ice Sheet

Seasonal Variations and Drivers of Surface Ocean pCO2 in the Seasonal Ice Zone of the Eastern Indian Sector, Southern Ocean

Onshore Diffusion of Circumpolar Deep Water

Contact Info

Product

Resources

About

Seasonal Variations and Drivers of Surface Ocean pCO₂ in the Seasonal Ice Zone of the Eastern Indian Sector, Southern Ocean