scholarly journals Abruptly attenuated carbon sequestration with Weddell Sea dense waters towards the end of the 21st century

2021 ◽  
Author(s):  
Cara Nissen ◽  
Ralph Timmermann ◽  
Mario Hoppema ◽  
Judith Hauck
Keyword(s):  
Carbon Sequestration ◽  
Deep Ocean ◽  
Weddell Sea ◽  
Carbon Accumulation ◽  
Ice Shelf ◽  
Warm Deep Water ◽  
High Emission ◽  
Ocean Carbon ◽  
High Emission Scenario ◽  
Model Setup

Abstract Antarctic Bottom Water formation, such as in the Weddell Sea, is an efficient vector for carbon sequestration on time scales of centuries. Possible changes in carbon sequestration under changing environmental conditions are unquantified to date, mainly due to difficulties in simulating the relevant processes on high-latitude continental shelves. Using a model setup including both ice-shelf cavities and oceanic carbon cycling, we demonstrate that by 2100, deep-ocean carbon accumulation in the southern Weddell Sea is abruptly attenuated to only 40% of the rate in the 1990s in a high-emission scenario, while still being 4-fold higher in the 2080s. Assessing deep-ocean carbon budgets and water mass transformations, we attribute this decline to an increased presence of Warm Deep Water on the southern Weddell Sea continental shelf, a 16% reduction in sea-ice formation, and a 79% increase in ice-shelf basal melt. Altogether, these changes lower the density and volume of newly formed bottom waters and reduce the associated carbon transport to the abyss.

scholarly journals Glacial – interglacial atmospheric CO<sub>2</sub> change: a simple "hypsometric effect" on deep-ocean carbon sequestration?

2006 ◽  
Vol 2 (5) ◽  
pp. 711-743 ◽  
Author(s):  
L. C. Skinner
Keyword(s):  
Carbon Sequestration ◽  
Carbon Storage ◽  
Ocean Circulation ◽  
Deep Water ◽  
Deep Sea ◽  
Storage Capacity ◽  
Deep Ocean ◽  
Contributing Factors ◽  
Carbon Reservoir ◽  
Ocean Carbon

Abstract. Given the magnitude and dynamism of the deep marine carbon reservoir, it is almost certain that past glacial – interglacial fluctuations in atmospheric CO2 have relied at least in part on changes in the carbon storage capacity of the deep sea. To date, physical ocean circulation mechanisms that have been proposed as viable explanations for glacial – interglacial CO2 change have focussed almost exclusively on dynamical or kinetic processes. Here, a simple mechanism is proposed for increasing the carbon storage capacity of the deep sea that operates via changes in the volume of southern-sourced deep-water filling the ocean basins, as dictated by the hypsometry of the ocean floor. It is proposed that a water-mass that occupies more than the bottom 3 km of the ocean will essentially determine the carbon content of the marine reservoir. Hence by filling this interval with southern-sourced deep-water (enriched in dissolved CO2 due to its particular mode of formation) the amount of carbon sequestered in the deep sea may be greatly increased. A simple box-model is used to test this hypothesis, and to investigate its implications. It is suggested that up to 70% of the observed glacial – interglacial CO2 change might be explained by the replacement of northern-sourced deep-water below 2.5 km water depth by its southern counterpart. Most importantly, it is found that an increase in the volume of southern-sourced deep-water allows glacial CO2 levels to be simulated easily with only modest changes in Southern Ocean biological export or overturning. If incorporated into the list of contributing factors to marine carbon sequestration, this mechanism may help to significantly reduce the "deficit" of explained glacial – interglacial CO2 change.

Attenuated carbon sequestration by Weddell Sea dense waters over the 21st century – an assessment with FESOM-REcoM

2021 ◽  
Author(s):  
Cara Nissen ◽  
Ralph Timmermann ◽  
Mario Hoppema ◽  
Judith Hauck
Keyword(s):  
Carbon Sequestration ◽  
Sea Ice ◽  
Continental Shelf ◽  
Bottom Water ◽  
Water Mass ◽  
Weddell Sea ◽  
Ice Shelf ◽  
Deep Waters ◽  
Water Formation ◽  
Water Mass Transformation

&lt;p&gt;Deep and bottom water formation regions have long been recognized to be efficient vectors for carbon transfer to depth, leading to carbon sequestration on time scales of centuries or more. Precursors of Antarctic Bottom Water (AABW) are formed on the Weddell Sea continental shelf as a consequence of buoyancy loss of surface waters at the ice-ocean or atmosphere-ocean interface, which suggests that any change in water mass transformation rates in this area affects global carbon cycling and hence climate. Many of the models previously used to assess AABW formation in present and future climates contained only crude representations of ocean-ice shelf interaction. Numerical simulations often featured spurious deep convection in the open ocean, and changes in carbon sequestration have not yet been assessed at all. Here, we present results from the global model FESOM-REcoM, which was run on a mesh with elevated grid resolution in the Weddell Sea and which includes an explicit representation of sea ice and ice shelves. Forcing this model with ssp585 scenario output from the AWI Climate Model, we assess changes over the 21&lt;sup&gt;st&lt;/sup&gt; century in the formation and northward export of dense waters and the associated carbon fluxes within and out of the Weddell Sea. We find that the northward transport of dense deep waters (&amp;#963;&lt;sub&gt;2&lt;/sub&gt;&gt;37.2 kg m&lt;sup&gt;-3&lt;/sup&gt; below 2000 m) across the SR4 transect, which connects the tip of the Antarctic Peninsula with the eastern Weddell Sea, declines from 4 Sv to 2.9 Sv by the year 2100. Concurrently, despite the simulated continuous increase in surface ocean CO&lt;sub&gt;2&lt;/sub&gt; uptake in the Weddell Sea over the 21&lt;sup&gt;st&lt;/sup&gt; century, the carbon transported northward with dense deep waters declines from 3.5 Pg C yr&lt;sup&gt;-1&lt;/sup&gt; to 2.5 Pg C yr&lt;sup&gt;-1&lt;/sup&gt;, demonstrating the dominant role of dense water formation rates for carbon sequestration. Using the water mass transformation framework, we find that south of SR4, the formation of downwelling dense waters declines from 3.5 Sv in the 1990s to 1.6 Sv in the 2090s, a direct result of the 18% lower sea-ice formation in the area, the increased presence of modified Warm Deep Water on the continental shelf, and 50% higher ice shelf basal melt rates. Given that the reduced formation of downwelling water masses additionally occurs at lighter densities in FESOM-REcoM in the 2090s, this will directly impact the depth at which any additional oceanic carbon uptake is stored, with consequences for long-term carbon sequestration.&lt;/p&gt;

scholarly journals Glacial – interglacial atmospheric CO<sub>2</sub> change: a possible "standing volume" effect on deep-ocean carbon sequestration

2009 ◽  
Vol 5 (3) ◽  
pp. 1259-1296 ◽  
Author(s):  
L. C. Skinner
Keyword(s):  
Carbon Sequestration ◽  
Deep Water ◽  
Deep Sea ◽  
Deep Ocean ◽  
Volume Effect ◽  
Biological Pump ◽  
Mixing Rates ◽  
Water Filling ◽  
Ocean Carbon ◽  
Oceanic Carbon

Abstract. So far, the exploration of possible mechanisms for glacial atmospheric CO2 draw-down and marine carbon sequestration has focussed almost exclusively on dynamic or kinetic processes (i.e. variable mixing-, equilibration- or export rates). Here an attempt is made to underline instead the possible importance of changes in the standing volumes of intra-oceanic carbon reservoirs (i.e. different water-masses) in setting the total marine carbon inventory. By way of illustration, a simple mechanism is proposed for enhancing the carbon storage capacity of the deep sea, which operates via an increase in the volume of relatively carbon-enriched AABW-like deep-water filling the ocean basins. Given the hypsometry of the ocean floor and an active biological pump, the water-mass that fills more than the bottom 3 km of the ocean will essentially determine the carbon content of the marine reservoir. A set of simple box-model experiments confirm the expectation that a deep sea dominated by AABW-like deep-water holds more CO2, prior to any additional changes in ocean overturning rate, biological export or ocean-atmosphere exchange. The magnitude of this "standing volume effect" might be as large as the contributions that have been attributed to carbonate compensation, the thermodynamic solubility pump or the biological pump for example. If incorporated into the list of factors that have contributed to marine carbon sequestration during past glaciations, this standing volume mechanism may help to reduce the amount of glacial – interglacial CO2 change that remains to be explained by other mechanisms that are difficult to assess in the geological archive, such as reduced mass transport or mixing rates in particular. This in turn could help narrow the search for forcing conditions capable of pushing the global carbon cycle between glacial and interglacial modes.

scholarly journals Glacial-interglacial atmospheric CO<sub>2</sub> change: a possible "standing volume" effect on deep-ocean carbon sequestration

2009 ◽  
Vol 5 (3) ◽  
pp. 537-550 ◽  
Author(s):  
L. C. Skinner
Keyword(s):  
Carbon Sequestration ◽  
Deep Water ◽  
Deep Ocean ◽  
Volume Effect ◽  
Lower Circumpolar Deep Water ◽  
Mixing Rates ◽  
Ocean Carbon ◽  
Oceanic Carbon ◽  
Global Carbon ◽  
Carbon Inventory

Abstract. So far, the exploration of possible mechanisms for glacial atmospheric CO2 drawdown and marine carbon sequestration has tended to focus on dynamic or kinetic processes (i.e. variable mixing-, equilibration- or export rates). Here an attempt is made to underline instead the possible importance of changes in the standing volumes of intra-oceanic carbon reservoirs (i.e. different water-masses) in influencing the total marine carbon inventory. By way of illustration, a simple mechanism is proposed for enhancing the marine carbon inventory via an increase in the volume of relatively cold and carbon-enriched deep water, analogous to modern Lower Circumpolar Deep Water (LCDW), filling the ocean basins. A set of simple box-model experiments confirm the expectation that a deep sea dominated by an expanded LCDW-like watermass holds more CO2, without any pre-imposed changes in ocean overturning rate, biological export or ocean-atmosphere exchange. The magnitude of this "standing volume effect" (which operates by boosting the solubility- and biological pumps) might be as large as the contributions that have previously been attributed to carbonate compensation, terrestrial biosphere reduction or ocean fertilisation for example. By providing a means of not only enhancing but also driving changes in the efficiency of the biological- and solubility pumps, this standing volume mechanism may help to reduce the amount of glacial-interglacial CO2 change that remains to be explained by other mechanisms that are difficult to assess in the geological archive, such as reduced mass transport or mixing rates in particular. This in turn could help narrow the search for forcing conditions capable of pushing the global carbon cycle between glacial and interglacial modes.

scholarly journals Seasonal copepod lipid pump promotes carbon sequestration in the deep North Atlantic

2015 ◽  
Vol 112 (39) ◽  
pp. 12122-12126 ◽  
Author(s):  
Sigrún Huld Jónasdóttir ◽  
André W. Visser ◽  
Katherine Richardson ◽  
Michael R. Heath
Keyword(s):  
Carbon Sequestration ◽  
North Atlantic ◽  
Deep Ocean ◽  
Calanus Finmarchicus ◽  
Carbon Equivalent ◽  
The North ◽  
Detrital Material ◽  
Mesopelagic Zone ◽  
The North Atlantic ◽  
Ocean Carbon

Estimates of carbon flux to the deep oceans are essential for our understanding of global carbon budgets. Sinking of detrital material (“biological pump”) is usually thought to be the main biological component of this flux. Here, we identify an additional biological mechanism, the seasonal “lipid pump,” which is highly efficient at sequestering carbon into the deep ocean. It involves the vertical transport and metabolism of carbon rich lipids by overwintering zooplankton. We show that one species, the copepod Calanus finmarchicus overwintering in the North Atlantic, sequesters an amount of carbon equivalent to the sinking flux of detrital material. The efficiency of the lipid pump derives from a near-complete decoupling between nutrient and carbon cycling—a “lipid shunt,” and its direct transport of carbon through the mesopelagic zone to below the permanent thermocline with very little attenuation. Inclusion of the lipid pump almost doubles the previous estimates of deep-ocean carbon sequestration by biological processes in the North Atlantic.

More extreme El Niño events reduce ocean carbon uptake in the future

2021 ◽  
Author(s):  
Enhui Liao ◽  
Laure Resplandy ◽  
Junjie Liu ◽  
Kevin Bowman
Keyword(s):  
Biogeochemical Model ◽  
Historical Period ◽  
Terrestrial Biosphere ◽  
The Future ◽  
Thermally Driven ◽  
High Emission ◽  
Ocean Carbon ◽  
High Emission Scenario ◽  
Flux Response ◽  
The Impact

&lt;p&gt;El Ni&amp;#241;o events weaken the strong natural oceanic source of CO&lt;sub&gt;2&lt;/sub&gt;&amp;#160;in the Tropical Pacific Ocean, partly offsetting the simultaneous release of CO&lt;sub&gt;2&lt;/sub&gt; from the terrestrial biosphere during these events. Yet, uncertainties in the magnitude of this ocean response and how it will respond to the projected increase in extreme El Ni&amp;#241;o in the future (Cai et al., 2014) limit our understanding of the global carbon cycle and its sensitivity to climate. Here, we examine the mechanisms controlling the air-sea CO&lt;sub&gt;2&lt;/sub&gt; flux response to El Ni&amp;#241;o events and how it will evolve in the future, using multidecadal ocean pCO&lt;sub&gt;2&lt;/sub&gt; observations in conjunction with CMIP6 Earth system models (ESMs) and a state&amp;#8208;of&amp;#8208;the&amp;#8208;art ocean biogeochemical model. We show that the magnitude, spatial extent, and duration of the anomalous ocean CO&lt;sub&gt;2&lt;/sub&gt; drawdown increased with El Ni&amp;#241;o intensity in the historical period. However, this relationship reverses in the CMIP6 projections under the high emission scenario.&amp;#160;ESMs project more intense El Ni&amp;#241;o events, but weaker CO&lt;sub&gt;2&lt;/sub&gt;&amp;#160;flux anomalies in the future.&amp;#160;This unexpected response&amp;#160;is controlled by two factors: a stronger compensation between thermally-driven outgassing and non-thermal drawdown (56% of the signal); and less pronounced wind anomalies limiting the impact of El Ni&amp;#241;o on air-sea CO&lt;sub&gt;2&lt;/sub&gt;&amp;#160;exchanges (26% of the signal). El Ni&amp;#241;os should no longer reinforce the net global oceanic sink in the future, but have a near-neutral effect or even release CO&lt;sub&gt;2&lt;/sub&gt;&amp;#160;to the atmosphere, reinforcing the concurrent release of CO&lt;sub&gt;2&lt;/sub&gt;&amp;#160;from the terrestrial biosphere.&lt;/p&gt;

scholarly journals Modeling the Influence of the Weddell Polynya on the Filchner–Ronne Ice Shelf Cavity

2019 ◽  
Vol 32 (16) ◽  
pp. 5289-5303 ◽  
Author(s):  
Kaitlin A. Naughten ◽  
Adrian Jenkins ◽  
Paul R. Holland ◽  
Ruth I. Mugford ◽  
Keith W. Nicholls ◽  
...  
Keyword(s):  
Continental Shelf ◽  
Deep Convection ◽  
Ocean Model ◽  
Shelf Break ◽  
Weddell Sea ◽  
Ice Shelf ◽  
Warm Deep Water ◽  
Regional Ocean Model ◽  
Ocean Models ◽  
Basal Melting

ABSTRACT Open-ocean polynyas in the Weddell Sea of Antarctica are the product of deep convection, which transports Warm Deep Water (WDW) to the surface and melts sea ice or prevents its formation. These polynyas occur only rarely in the observational record but are a near-permanent feature of many climate and ocean simulations. A question not previously considered is the degree to which the Weddell polynya affects the nearby Filchner–Ronne Ice Shelf (FRIS) cavity. Here we assess these effects using regional ocean model simulations of the Weddell Sea and FRIS, where deep convection is imposed with varying area, location, and duration. In these simulations, the idealized Weddell polynyas consistently cause an increase in WDW transport onto the continental shelf as a result of density changes above the shelf break. This leads to saltier, denser source waters for the FRIS cavity, which then experiences stronger circulation and increased ice shelf basal melting. It takes approximately 14 years for melt rates to return to normal after the deep convection ceases. Weddell polynyas similar to those seen in observations have a modest impact on FRIS melt rates, which is within the range of simulated interannual variability. However, polynyas that are larger or closer to the shelf break, such as those seen in many ocean models, trigger a stronger response. These results suggest that ocean models with excessive Weddell Sea convection may not be suitable boundary conditions for regional models of the Antarctic continental shelf and ice shelf cavities.

scholarly journals Geographical variations in the effectiveness and side effects of deep ocean carbon sequestration

2011 ◽  
Vol 38 (17) ◽  
pp. n/a-n/a ◽  
Author(s):  
Andy Ridgwell ◽  
Thomas J. Rodengen ◽  
Karen E. Kohfeld
Keyword(s):  
Carbon Sequestration ◽  
Side Effects ◽  
Deep Ocean ◽  
Geographical Variations ◽  
Ocean Carbon

scholarly journals Sensitivity of the Weddell Sea sector ice streams to sub-shelf melting and surface accumulation

2013 ◽  
Vol 7 (6) ◽  
pp. 5475-5508 ◽  
Author(s):  
A. P. Wright ◽  
A. M. Le Brocq ◽  
S. L. Cornford ◽  
M. J. Siegert ◽  
R. G. Bingham ◽  
...  
Keyword(s):  
Adaptive Mesh Refinement ◽  
Reference Model ◽  
Deep Ocean ◽  
Adaptive Mesh ◽  
Weddell Sea ◽  
Ice Shelf ◽  
Ice Streams ◽  
Deep Ocean Water ◽  
Grounding Line ◽  
The Impact

Abstract. A recent ocean modelling study indicates that possible changes in circulation may bring warm deep ocean water into direct contact with the grounding lines of the Filchner-Ronne ice streams, suggesting the potential for future ice losses from this sector equivalent to ~ 0.3 m of sea-level rise. Significant advancements have been made in our knowledge of both the basal topography and ice velocity in the Weddell Sea sector, thus enabling an assessment to be made of the relative sensitivities of the diverse collection of ice streams feeding the Filchner-Ronne Ice Shelf. Here we use the BISICLES ice sheet model, which employs adaptive-mesh refinement to resolve grounding line dynamics, to carry out such an assessment. The impact of perturbations to the surface and sub-shelf mass balance forcing fields from our 2000 yr "reference" model run indicate that both the Institute and Möller Ice Streams are highly sensitive to changes in basal melting either near to their respective grounding lines, or in the region of the ice rises within the Filchner-Ronne Ice Shelf. These same perturbations have little impact, however, on Rutford, Carlson or Foundation ice streams, while Evans Ice Stream is found to enter a phase of unstable retreat only after melt at its grounding line has increased by an order-of-magnitude from likely present-day values.

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