Systematic study of the impact of fresh water fluxes on the glacial carbon cycle

Bouttes, Nathaëlle; Roche, Didier M.; Paillard, Didier

doi:10.5194/cp-8-589-2012

Cited by 31 publications

(35 citation statements)

References 42 publications

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“…Notably, the initial (within the first 250 yr) rapid response in CO 2 in Schmittner and Galbraith (2008) is attributed to CO 2 release from the terrestrial biosphere (triggered by cooling associated with the AMOC reduction) and not to physical or biogeochemical components of the Southern Ocean carbon cycle. However, the response of terrestrial vegetation models and the interplay between ocean and vegetation responses is known to be highly model-dependent (Bouttes et al, 2012). Recent studies also emphasise the sensitivity of the timescales of ocean ventilation to model resolution; at least under modern boundary conditions, meso-scale eddy-resolving ocean models suggest much faster ventilation times than the coarser resolution models that are currently used for palaeo-simulations (Maltrud et al, 2010).…”

Section: Resultsmentioning

confidence: 99%

Tightened constraints on the time-lag between Antarctic temperature and CO<sub>2</sub> during the last deglaciation

2012

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Abstract. Antarctic ice cores provide clear evidence of a close coupling between variations in Antarctic temperature and the atmospheric concentration of CO 2 during the glacial/interglacial cycles of at least the past 800-thousand years. Precise information on the relative timing of the temperature and CO 2 changes can assist in refining our understanding of the physical processes involved in this coupling. Here, we focus on the last deglaciation, 19 000 to 11 000 yr before present, during which CO 2 concentrations increased by ∼ 80 parts per million by volume and Antarctic temperature increased by ∼ 10 • C. Utilising a recently developed proxy for regional Antarctic temperature, derived from five near-coastal ice cores and two ice core CO 2 records with high dating precision, we show that the increase in CO 2 likely lagged the increase in regional Antarctic temperature by less than 400 yr and that even a short lead of CO 2 over temperature cannot be excluded. This result, consistent for both CO 2 records, implies a faster coupling between temperature and CO 2 than previous estimates, which had permitted up to millennial-scale lags.

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Section: Resultsmentioning

confidence: 99%

Tightened constraints on the time-lag between Antarctic temperature and CO<sub>2</sub> during the last deglaciation

2012

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“…The occurrence of Heinrich event 6 did not only have an influence on ocean circulation, but the effects of such events are recorded in chemical signals worldwide, including the Cariaco Basin [ Peterson et al , ], Hulu Cave in China [ Wang , ], Arabian Sea [ Schulz et al , ], Santa Barbara Basin [ Behl and Kennett , ], and the western Pacific Warm Pool [ Shiau et al , ], due to the global impact of the AMOC and related changes in the position of the intertropical convergence zone. Although some model results indicate that a weakening of the AMOC may have resulted in an increase in carbon storage in terrestrial vegetation [e.g., Schmittner and Galbraith , ; Bouttes et al , ], others indicate that a decrease in these stocks is possible [e.g., Menviel et al , ; Bozbiyik et al , ].…”

Section: Discussionmentioning

confidence: 99%

Evolution of the stable carbon isotope composition of atmospheric CO₂ over the last glacial cycle

et al. 2016

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We present new 13 C measurements of atmospheric CO 2 covering the last glacial/interglacial cycle, complementing previous records covering Terminations I and II. Most prominent in the new record is a significant depletion in 13 C(atm) of 0.5‰ occurring during marine isotope stage (MIS) 4, followed by an enrichment of the same magnitude at the beginning of MIS 3. Such a significant excursion in the record is otherwise only observed at glacial terminations, suggesting that similar processes were at play, such as changing sea surface temperatures, changes in marine biological export in the Southern Ocean (SO) due to variations in aeolian iron fluxes, changes in the Atlantic meridional overturning circulation, upwelling of deep water in the SO, and long-term trends in terrestrial carbon storage. Based on previous modeling studies, we propose constraints on some of these processes during specific time intervals. The decrease in 13 C(atm) at the end of MIS 4 starting approximately 64 kyr B.P. was accompanied by increasing [CO 2 ]. This period is also marked by a decrease in aeolian iron flux to the SO, followed by an increase in SO upwelling during Heinrich event 6, indicating that it is likely that a large amount of 13 C-depleted carbon was transferred to the deep oceans previously, i.e., at the onset of MIS 4. Apart from the upwelling event at the end of MIS 4 (and potentially smaller events during Heinrich events in MIS 3), upwelling of deep water in the SO remained reduced until the last glacial termination, whereupon a second pulse of isotopically light carbon was released into the atmosphere.

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“…Any changes in the ocean's DIC and alkalinity content that impact on the global average carbonate saturation state will tend to be restored (i.e., eliminated) by adjustments in the position of the lysocline (and possibly the CCD), which is referred to as “carbonate compensation”(Broecker, ; Broecker & Peng, ; Sigman et al, ). Over millennial time scales, the distinct chemical signatures of northern versus southern sourced water masses make sedimentary carbonate preservation specifically in the South Atlantic primarily dependent on prevailing ocean circulation patterns that may have shifted rapidly in the past (Gottschalk et al, ; Henry et al, ; Keigwin & Jones, ; McManus et al, ), with implications for atmospheric CO 2 levels (e.g., Bouttes et al, ; Schmittner & Galbraith, ). The sedimentary carbonate record of the deep Atlantic hence integrates the influence of various ocean processes that operate on different time scales (Hodell et al, ).…”

Section: Introductionmentioning

confidence: 99%

Past Carbonate Preservation Events in the Deep Southeast Atlantic Ocean (Cape Basin) and Their Implications for Atlantic Overturning Dynamics and Marine Carbon Cycling

Gottschalk

Hodell

Skinner

et al. 2018

Paleoceanog and Paleoclimatol

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Micropaleontological and geochemical analyses reveal distinct millennial‐scale increases in carbonate preservation in the deep Southeast Atlantic (Cape Basin) during strong and prolonged Greenland interstadials that are superimposed on long‐term (orbital‐scale) changes in carbonate burial. These data suggest carbonate oversaturation of the deep Atlantic and a strengthened Atlantic Meridional Overturning Circulation (AMOC) during the most intense Greenland interstadials. However, proxy evidence from outside the Cape Basin indicates that AMOC changes also occurred during weaker and shorter Greenland interstadials. Here we revisit the link between AMOC dynamics and carbonate saturation in the deep Cape Basin over the last 400 kyr (sediment cores TN057‐21, TN057‐10, and Ocean Drilling Program Site 1089) by reconstructing centennial changes in carbonate preservation using millimeter‐scale X‐ray fluorescence (XRF) scanning data. We observe close agreement between variations in XRF Ca/Ti, sedimentary carbonate content, and foraminiferal shell fragmentation, reflecting a common control primarily through changing deep water carbonate saturation. We suggest that the high‐frequency (suborbital) component of the XRF Ca/Ti records indicates the fast and recurrent redistribution of carbonate ions in the Atlantic basin via the AMOC during both long/strong and short/weak North Atlantic climate anomalies. In contrast, the low‐frequency (orbital) XRF Ca/Ti component is interpreted to reflect slow adjustments through carbonate compensation and/or changes in the deep ocean respired carbon content. Our findings emphasize the recurrent influence of rapid AMOC variations on the marine carbonate system during past glacial periods, providing a mechanism for transferring the impacts of North Atlantic climate anomalies to the global carbon cycle via the Southern Ocean.

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Systematic study of the impact of fresh water fluxes on the glacial carbon cycle

Cited by 31 publications

References 42 publications

Tightened constraints on the time-lag between Antarctic temperature and CO<sub>2</sub> during the last deglaciation

Tightened constraints on the time-lag between Antarctic temperature and CO<sub>2</sub> during the last deglaciation

Evolution of the stable carbon isotope composition of atmospheric CO₂ over the last glacial cycle

Past Carbonate Preservation Events in the Deep Southeast Atlantic Ocean (Cape Basin) and Their Implications for Atlantic Overturning Dynamics and Marine Carbon Cycling

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Systematic study of the impact of fresh water fluxes on the glacial carbon cycle

Cited by 31 publications

References 42 publications

Tightened constraints on the time-lag between Antarctic temperature and CO&lt;sub&gt;2&lt;/sub&gt; during the last deglaciation

Tightened constraints on the time-lag between Antarctic temperature and CO&lt;sub&gt;2&lt;/sub&gt; during the last deglaciation

Evolution of the stable carbon isotope composition of atmospheric CO2 over the last glacial cycle

Past Carbonate Preservation Events in the Deep Southeast Atlantic Ocean (Cape Basin) and Their Implications for Atlantic Overturning Dynamics and Marine Carbon Cycling

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Tightened constraints on the time-lag between Antarctic temperature and CO<sub>2</sub> during the last deglaciation

Tightened constraints on the time-lag between Antarctic temperature and CO<sub>2</sub> during the last deglaciation

Evolution of the stable carbon isotope composition of atmospheric CO₂ over the last glacial cycle