The role of tides in bottom water export from the western Ross Sea

Bowen, Melissa; Fernandez, Denise; Forcén-Vázquez, Aitana; Gordon, Arnold L.; Huber, Bruce A.; Castagno, Pasquale; Falco, Pierpaolo

doi:10.1038/s41598-021-81793-5

Cited by 21 publications

(22 citation statements)

References 39 publications

(78 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…AABW plays a crucial role in the global overturning circulation, in abyssal ventilation and in the cross-basin transport of heat, salt, carbon, nutrients and numerous other tracers (Killworth, 1983;Johnson, 2008;Orsi, 2010). The principal locations for the formation of the source waters of AABW are the Weddell and Ross Seas adjacent to the large ice shelves (Orsi et al, 1999;van Caspel et al, 2015;Kerr et al, 2018;Bowen et al, 2021). Filchner Ronne Ice Shelf (FRIS) is located at the southern boundary of the Weddell Sea and represents 28% of the total Antarctic ice shelf area (Fig.…”

Section: Introductionmentioning

confidence: 99%

“…We choose to keep all other ice shelves closed with prescribed melt rates injected at the mouth of the front using the method described by Mathiot et al (2017). RIS, FRIS and LCIS were chosen due to their role in the formation and setting of properties of the parent waters of AABW (Kerr et al, 2018;Bowen et al, 2021), and due to their large size and thus practicality of realistically simulating their sub-ice shelf cavities in a global ocean 1° setup. We choose to explore the changes in circulation, melt rates, and water mass properties in a forced scenario with fixed cavity geometry as coupling can introduce further biases and obscure the changes attributed to sub-ice shelf circulation.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Improving Antarctic Bottom Water precursors in NEMO for climate applications

Hutchinson

Deshayes

Éthé

et al. 2023

Preprint

View full text Add to dashboard Cite

Abstract. The world’s largest ice shelves are found in the Antarctic Weddell and Ross Seas where complex interactions between the atmosphere, sea ice, ice shelves and ocean transform shelf waters into High Salinity Shelf Water (HSSW) and Ice Shelf Water (ISW), the parent waters of Antarctic Bottom Water (AABW). This process feeds the lower limb of the global overturning circulation as AABW, the world’s densest and deepest water-mass, spreads outwards from Antarctica. None of the coupled climate models contributing to CMIP6 directly simulated ocean-ice shelf interactions, thereby omitting a potentially critical piece of the climate puzzle. As a first step towards better representing these processes in a global ocean model, we run a 1° resolution forced configuration of NEMO (eORCA1) to explicitly simulate circulation beneath Filchner-Ronne (FRIS), Larsen C (LCIS), and Ross (RIS) ice shelves. These locations are thought to supply the majority of the source waters for AABW and so melt in all other cavities is provisionally prescribed. Results show that the grid resolution of 1° is sufficient to produce melt rate patterns and net melt rates of FRIS (117 ± 21 Gt/yr), LCIS (36 + 7 Gt/yr) and RIS (112 + 22 Gt/yr) that agree well with both high resolution models and satellite measurements. Most notably, allowing sub-ice shelf circulation reduces salinity biases (0.1 psu), produces the previously unresolved water mass ISW, and re-organises the shelf circulation to bring the regional model hydrography closer to observations. A change in AABW within the Weddell and Ross Seas towards colder, fresher values is identified but the magnitude is limited by the absence of a realistic overflow. This study presents a NEMO configuration that can be used for climate applications with improved realism of the Antarctic continental shelf circulation and a better representation of the precursors of AABW.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Improving Antarctic Bottom Water precursors in NEMO for climate applications

Hutchinson

Deshayes

Éthé

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…The AABW is produced by the tidal mixing of the Dense Shelf Water (DSW) with the Circumpolar Deep Water (CDW) along the continental shelf margins in the western sector (Whitworth and Orsi, 2006;Castagno et al, 2017;Bowen et al, 2021) and it contributes significantly to the ventilation of the deep layer of the Southern Ocean (Orsi and Wiederwohl, 2009). Therefore, it plays an important role in sequestering CO 2 from the atmosphere and transferring it into the deep ocean (Caldeira and Duffy, 2000;Sabine et al, 2004;Sandrini et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Carbonate system data tracing freshwater inflow into the Ross Sea through the eastern gate and along the Ross Ice Shelf (Antarctica)

et al. 2022

Self Cite

View full text Add to dashboard Cite

The eastern Ross Sea is a key area to understand the role of the Amundsen Sea inflow of freshwater that can influence the Ross Sea water properties and salt budget. A survey was carried out in the eastern Ross Sea during the austral summer 2019–20 to evaluate the contribution of the Amundsen Sea Water (ASW) to the salinity variability. A total of 248 seawater samples were collected f\or the analysis of total alkalinity (AT) and pH. The data collected were used together with temperature and salinity to obtain a full description of the carbonate system properties including total inorganic carbon (CT), CO2 partial pressure (pCO2), calcium carbonate saturation state of aragonite and calcite (Ω), and Revelle factor. Moreover, we estimated the anthropogenic carbon (Cant) throughout the TrOCA method to better understand the carbon cycle, also considering the effect of atmospheric CO2 uptake on ocean acidification. We used principal component analysis (PCA) to investigate the major controls on the carbonate system parameters with the aim of defining their sensitivity as chemical tracers. The changes in carbonate chemistry in surface waters were mainly due to the physical properties. AT and pH traced the entry of the ASW showing limited mixing between water masses on the shelf area. Shelf waters were enriched in Cant, which resulted lower than the estimated value for shelf waters produced in western Ross Sea.

show abstract

“…HSSW is present at depth year-round in TNB, but new HSSW is produced only during austral winter, when salinification of surface waters via brine rejection has broken down lingering stratification from summer ice melt and solar radiation, allowing full water column convection to occur [23][24][25] . While some of the HSSW produced in TNB is converted to Ice Shelf Water (ISW) through its interaction with the local glaciers 22 or exported southward under the Drygalski Ice Tongue 12,19 , most of it spreads northward through the Drygalski Basin, taking about 8 months to reach the Drygalski Trough 26 . It ultimately exits the continental shelf as dense, tidally-modulated gravity plumes 20,21,[26][27][28] .…”

mentioning

confidence: 99%

“…While some of the HSSW produced in TNB is converted to Ice Shelf Water (ISW) through its interaction with the local glaciers 22 or exported southward under the Drygalski Ice Tongue 12,19 , most of it spreads northward through the Drygalski Basin, taking about 8 months to reach the Drygalski Trough 26 . It ultimately exits the continental shelf as dense, tidally-modulated gravity plumes 20,21,[26][27][28] . Though the circulation of HSSW within TNB and its export via the Drygalski Trough are generally understood 12,22 , its production rate is poorly constrained; Previous estimates using net heat fluxes parametrized from reanalysis data 29 and simulated passive tracer experiments in a high-resolution regional model of the Ross Sea 19 differ by ~0.9 𝑆𝑣, a discrepancy on the same order of magnitude as the estimated transport of TNB HSSW northward to the shelf break.…”

mentioning

confidence: 99%

High Salinity Shelf Water production in Terra Nova Bay, Ross Sea from high-resolution near-surface salinity observations

Miller

Zappa

Gordon

et al. 2022

Preprint

View full text Add to dashboard Cite

High Salinity Shelf Water (HSSW) is a precursor to Antarctic Bottom Water (AABW), a water mass that facilitates the sequestration of atmospheric heat and carbon into the deep ocean. The salinity of HSSW in the Ross Sea is sensitive to both local and broader regional forcing, with implications for the density of downstream AABW and the ocean’s ability to buffer against climate change. One poorly constrained source of HSSW variability in this region is its rate of production within Terra Nova Bay (TNB) in the western Ross Sea. Here, we use an unprecedented set of near-surface salinity, current velocity, and acoustic surface tracking timeseries, collected from a mooring in TNB in austral winter 2017, to estimate HSSW production rates. In one of few studies at the resolution of individual katabatic wind events, we find that HSSW production rates correlate with katabatic wind event frequency in early winter and with frequency, strength, and duration in late winter, suggesting a complex dependence on polynya dynamics. We calculate an average HSSW production rate of ~0.6 Sverdrups (106 m3 s-1)that allows us to validate an approach for estimating production rates from parametrized net surface heat fluxes, which we use to examine interannual variability in production rates across the decade. Though further mooring-based estimates are needed for confirmation, results suggest HSSW production in TNB has been mostly increasing since 2015 and could play a previously unrecognized role in the recently observed recovery of HSSW salinity in this region.

show abstract

The role of tides in bottom water export from the western Ross Sea

Cited by 21 publications

References 39 publications

Improving Antarctic Bottom Water precursors in NEMO for climate applications

Improving Antarctic Bottom Water precursors in NEMO for climate applications

Carbonate system data tracing freshwater inflow into the Ross Sea through the eastern gate and along the Ross Ice Shelf (Antarctica)

High Salinity Shelf Water production in Terra Nova Bay, Ross Sea from high-resolution near-surface salinity observations

Contact Info

Product

Resources

About