The Roles of Wind and Sea Ice in Driving the Deglacial Change in the Southern Ocean Upwelling: A Modeling Study

Mandal, G. S.; Lee, Shih‐Yu; Yu, Jingshan

doi:10.3390/su13010353

Cited by 5 publications

(4 citation statements)

References 98 publications

(175 reference statements)

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“…For example, the TraCE-21ka model replicated the Asian-African monsoon [88], El Niño [89], the highlatitude seasonal temperature [90], the AMOC transport, and the SH regional sea surface temperature [5]. In addition, the model reasonably simulated the present-day atmospheric circulation and sea surface temperature in the SO [49,91].…”

Section: Model Performancementioning

confidence: 83%

The Roles of Orbital and Meltwater Climate Forcings on the Southern Ocean Dynamics during the Last Deglaciation

Mandal

Lee

2022

Sustainability

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The last deglacial climate evolution, from 19 to 9 thousand years before the present, represents the vital role of feedback in the Earth’s climate system. The Southern Ocean played a fundamental role by exchanging nutrients and carbon-rich deep ocean water with the surface during the last deglaciation. This study employs a fully coupled Earth system model to investigate the evolution of Southern Ocean dynamics and the roles of changes in orbital and meltwater forcings during the last deglaciation. The simulation supports that the Southern Ocean upwelling was primarily driven by windstress. The results show that the melting and formation of Antarctic sea ice feedback influenced Southern Ocean surface buoyancy flux. The increase in Antarctic sea ice melt-induced freshwater flux resulted in a steepened north-south surface salinity gradient in the Southern Ocean, which enhanced the upwelling. The single-forcing experiments indicate that the deglacial changes in orbital insolation influenced the Southern Ocean upwelling. The experiments also highlight the dominant role of Northern Hemisphere meltwater discharge in the upper and lower branch of the Meridional Overturning Circulation. Furthermore, orbital forcing shows lesser deglacial Antarctic sea ice retreat than the Northern Hemisphere meltwater forcing, which follows the bipolar seesaw mechanism.

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Section: Model Performancementioning

confidence: 83%

The Roles of Orbital and Meltwater Climate Forcings on the Southern Ocean Dynamics during the Last Deglaciation

Mandal

Lee

2022

Sustainability

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“…Previous studies have shown that the melting of Antarctic sea ice releases freshwater, which increases the buoyancy of Southern Ocean upwelled water (Iudicone et al, 2008) and strengthened the upper limb of the ocean meridional overturning circulation (Abernathey et al, 2016;Saenko et al, 2002). Furthermore, numerical simulations have confirmed the importance of freshwater fluxes in determining changes in Southern Ocean upwelling during the last deglacial period (Mandal et al, 2021;Mandal et al, 2022;Morrison et al, 2011).…”

Section: Introductionmentioning

confidence: 82%

“…The paleoclimatology community recognizes that the Southern Ocean overturning circulation is primarily driven by wind (Anderson et al, 2009;Menviel et al, 2018). Several studies, however, have found that changes in buoyancy flux caused by freshwater discharge (Abernathey et al, 2016;Liu et al, 2021), ocean eddies (Lauderdale et al, 2017), topography (Liu et al, 2021), and Antarctic sea ice feedback (Ferrari et al, 2014;Jansen & Nadeau, 2016;Mandal et al, 2021;Mandal et al, 2022;Marzocchi & Jansen, 2017;Stein et al, 2020) contribute to the Southern Ocean dynamical changes during the most recent deglacial period. As a result, it is critical to comprehend the role of Antarctic sea ice in surface buoyancy flux, which influences the Southern Ocean overturning circulation.…”

Section: Introductionmentioning

confidence: 99%

The Influence of Antarctic Sea Ice Distribution on the Southern Ocean Overturning Circulation for the Past 20,000 Years

Mandal

Lee

2023

Iecg 2022

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The changes in Southern Ocean physics are dynamically linked to westerly winds, ocean currents, and the distribution of Antarctic sea ice in the Southern Hemisphere. As a result, it is critical to comprehend the response of the Southern Ocean physics to the distribution of Antarctic sea ice on a basin scale. This modeling study employs a fully coupled Earth system model to investigate the effect of Antarctic Sea ice distribution on the Southern Ocean dynamics during the past twenty thousand years before the present. The findings show that the formation and melting of sea ice have an effect on the distribution of surface buoyancy flux over the Southern Ocean. The simulated sea ice edge (grid points in the ice model have a sea ice concentration above 5%) in the Southern Ocean almost demarcates the borderline between the lower and upper meridional overturning cells. The seemingly-permanent Antarctic sea ice edge (grid points in the ice model with a sea ice concentration greater than 80%) coincides with the shift of buoyancy flux from positive (buoyancy gain) to negative (buoyancy loss). Furthermore, the negative surface buoyancy flux zone has shifted polewards for the past twenty thousand years, with the exception of about 14.1 thousand years. Our findings show that the Antarctic sea ice feedback affects the surface buoyancy flux, which in turn affects the overturning circulation in the Southern Ocean.

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“…However, relatively stable LGM atmospheric CO 2 levels suggest that this was likely not a significant source of CO 2 to the atmosphere at this time. Model simulations have projected that reduced deep ocean ventilation was linked to expanded sea ice along with equatorward shifted Westerlies and Southern Ocean fronts in the LGM (Chen & Wang, 2021; Ferrari et al., 2014; Mandal et al., 2021; Menviel et al., 2015; Russell et al., 2006; Toggweiler et al., 2006). These new data are the first to clarify that the individual fronts did not move in sync or in parallel and identifies that the narrowing of the SAZ in the Indian Ocean was a significant process sequestering CO 2 .…”

Section: Lgmmentioning

confidence: 99%

Deglacial Carbon Escape From the Northern Rim of the Southern Ocean

Umling,

Sikes,

Rafter

et al. 2024

Geophysical Research Letters

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The Southern Ocean regulates atmospheric CO2 and Earth's climate as a critical region for air‐sea gas exchange, delicately poised between being a CO2 source and sink. Here, we estimate how long a water mass has remained isolated from the atmosphere and utilize 14C/12C ratios (Δ14C) to trace the pathway and escape route of carbon sequestered in the deep ocean through the mixed layer to the atmosphere. The position of our core at the northern margin of the Southern Indian Ocean, tracks latitudinal shifts of the Southern Ocean frontal zones across the deglaciation. Our results suggest an expanded glacial Antarctic region trapped CO2, whereas deglacial expansion of the subantarctic permitted ventilation of the trapped CO2, contributing to a rapid atmospheric CO2 rise. We identify frontal positions as a key factor balancing CO2 outgassing versus sequestration in a region currently responsible for nearly half of global ocean CO2 uptake.

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The Roles of Wind and Sea Ice in Driving the Deglacial Change in the Southern Ocean Upwelling: A Modeling Study

Cited by 5 publications

References 98 publications

The Roles of Orbital and Meltwater Climate Forcings on the Southern Ocean Dynamics during the Last Deglaciation

The Roles of Orbital and Meltwater Climate Forcings on the Southern Ocean Dynamics during the Last Deglaciation

The Influence of Antarctic Sea Ice Distribution on the Southern Ocean Overturning Circulation for the Past 20,000 Years

Deglacial Carbon Escape From the Northern Rim of the Southern Ocean

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