Sources and fates of silicon in the ocean: the role of diatoms in the climate and glacial cycles

Dugdale, Richard C.; Wilkerson, Frances P.

doi:10.3989/scimar.2001.65s2141

Cited by 35 publications

(34 citation statements)

References 53 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the Amazon plume area, dissolved Si concentrations are as high as 13 mM, and in this area diatoms account for 29% of primary productivity, compared with 3% at open ocean Western Equatorial Atlantic (WEA) stations where concentrations of Si are as low as 0.2 mM [Shipe et al, 2006]. This supports the work of Dugdale and Wilkerson [2001], which showed in a culture study that diatoms can outcompete other phytoplankton for nitrate as long as there is enough available silicic acid. Therefore if SO-derived water upwelled at the equator during glacial periods containing significantly more dissolved Si (and/or a higher Si:N ratio) than today, then diatoms would have been at a competitive advantage over other taxa for nutrients such as nitrate.…”

Section: Introductionsupporting

confidence: 77%

“…[42] Increased silicic acid availability might be expected to have the largest impact on diatom productivity (and therefore also on coccolithophorid productivity) in areas rich in other nutrients [Dugdale and Wilkerson, 2001], namely the upwelling zone in the eastern equatorial Atlantic. While records of CaCO 3 accumulation and productivity in the eastern part of the basin do not consistently show a glacial decrease in CaCO 3 productivity, some do show such a trend, and most records in the western Atlantic also indicate decreased glacial CaCO 3 production.…”

Section: Implications For the Salhmentioning

confidence: 99%

See 1 more Smart Citation

Opal burial in the equatorial Atlantic Ocean over the last 30 ka: Implications for glacial‐interglacial changes in the ocean silicon cycle

et al. 2007

View full text Add to dashboard Cite

The Silicic Acid Leakage Hypothesis (SALH) suggests that, during glacial periods, excess silicic acid was transported from the Southern Ocean to lower latitudes, which favored diatom production over coccolithophorid production and caused a drawdown of atmospheric CO2. Downcore records of 230Th‐normalized opal fluxes and 231Pa/230Th ratios from seven equatorial Atlantic cores were used to reconstruct diatom productivity over the past 30 ka (where a is years) and to test the SALH. Downcore records of 231Pa/230Th ratios and opal fluxes are highly correlated, suggesting that they constitute a production‐based record of opal flux. Opal flux records support the SALH in that glacial opal burial exceeded Holocene burial by 1.8 Gt opal/ka in the area 0°–40°W and 5°N–5°S. Earlier results from the eastern equatorial Pacific Ocean showed the opposite trend, with greater Holocene than glacial opal burial, but approximately the same magnitude of difference between glacial and interglacial opal burial. We suggest four (nonexclusive) scenarios to explain the data from both basins: (1) Increased upwelling in the equatorial Atlantic and El Niño–like conditions suppressing upwelling in the eastern equatorial Pacific altered the overall nutrient supply to both basins; (2) Si leaked from the Southern Ocean because of Fe fertilization, but was prevented from upwelling in the equatorial Pacific because of El Niño–like conditions during the LGM; (3) Si leaked from the Southern Ocean because diatom productivity was limited by increased sea ice extent and was again prevented from upwelling in the equatorial Pacific; or (4) changes in ocean circulation related to the decreased input of Agulhas water to the glacial South Atlantic provided excess dissolved Si to the equatorial Atlantic Ocean. A deglacial opal pulse is seen in both the Atlantic and Pacific Oceans. All four scenarios and the presence of the common deglacial opal pulse suggest a common driver in the Southern Ocean.

show abstract

Section: Introductionsupporting

confidence: 77%

Section: Implications For the Salhmentioning

confidence: 99%

Opal burial in the equatorial Atlantic Ocean over the last 30 ka: Implications for glacial‐interglacial changes in the ocean silicon cycle

et al. 2007

View full text Add to dashboard Cite

show abstract

“…This creates a linkage between the Antarctic and Subantarctic where nutrient dynamics in the south set the initial nutrient content of the water delivered to the north. The preferential Si depletion known to occur between the SACCF and the APF thus likely contributes to the low-Si high-nitrate character of the modern-day APFZ and Subantarctic (Dugdale et al 1995;Pondaven et al 2000Brzezinski et al 2003. These linkages would cause any perturbations to nutrient depletion ratios occurring to the south of the APF during glacial periods to have significant effects to the north in the Subantarctic.…”

mentioning

confidence: 99%

Control of silica production by iron and silicic acid during the Southern Ocean Iron Experiment (SOFeX)

Brzezinski

Jones

Demarest

2005

Limnology & Oceanography

View full text Add to dashboard Cite

We examined the role of Si limitation in mediating the response of siliceous biomass and silica production to mesoscale Fe fertilization in the high-silicic acid high-nitrate waters of the Antarctic and in the low-silicic acid high-nitrate waters of the Subantarctic during austral summer. Iron fertilization stimulated biogenic silica production and silicic acid depletion in both regions. Si limitation significantly curtailed the response of silica production to Fe in the Subantarctic, but not in the Antarctic. Additions of silicic acid to Fe-enriched waters of the Subantarctic more than doubled specific silica production rates beyond the increase caused by Fe alone. This result, combined with the presence of Si limitation both inside and outside of the fertilized patch in the Subantarctic, indicates that silica production in the Subantarctic is regulated by both Fe and Si during austral summer. Fe increased the ability of Subantarctic diatom assemblages to take up low concentrations of Si over an order of magnitude by increasing maximum uptake rates and lowering half-saturation constants for silicic acid uptake. Our observations indicate that the dramatic gradient in Si availability across the Antarctic Circumpolar Current exerts a strong control on the contribution of diatoms to new production following Fe enrichment in the Southern Ocean during austral summer. With sufficient Fe to allow nitrate depletion, the abundant silicic acid in the Antarctic would allow diatoms to dominate nitrate use; however, low silicic acid concentrations in the Subantarctic would restrict the fraction of available nitrate that would be consumed by diatoms to ca. 5%.

show abstract

“…S1). The increase in silicate availability in the EEP would favor diatom production over coccolithophores, which cannot compete with diatoms when there is enough SiðOHÞ 4 available (8)(9)(10). This causes a reduction in calcite production, affecting the CaCO 3 to organic carbon rain ratio to the deep ocean and ultimately, a lowering of atmospheric CO 2 of 40 to 50 ppm (5,11).…”

mentioning

confidence: 99%

Eastern Equatorial Pacific productivity and related-CO ₂ changes since the last glacial period

Calvo

Pelejero

Pena

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Understanding oceanic processes, both physical and biological, that control atmospheric CO 2 is vital for predicting their influence during the past and into the future. The Eastern Equatorial Pacific (EEP) is thought to have exerted a strong control over glacial/interglacial CO 2 variations through its link to circulation and nutrientrelated changes in the Southern Ocean, the primary region of the world oceans where CO 2 -enriched deep water is upwelled to the surface ocean and comes into contact with the atmosphere. Here we present a multiproxy record of surface ocean productivity, dust inputs, and thermocline conditions for the EEP over the last 40,000 y. This allows us to detect changes in phytoplankton productivity and composition associated with increases in equatorial upwelling intensity and influence of Si-rich waters of subAntarctic origin. Our evidence indicates that diatoms outcompeted coccolithophores at times when the influence of Si-rich Southern Ocean intermediate waters was greatest. This shift from calcareous to noncalcareous phytoplankton would cause a lowering in atmospheric CO 2 through a reduced carbonate pump, as hypothesized by the Silicic Acid Leakage Hypothesis. However, this change does not seem to have been crucial in controlling atmospheric CO 2 , as it took place during the deglaciation, when atmospheric CO 2 concentrations had already started to rise. Instead, the concomitant intensification of Antarctic upwelling brought large quantities of deep CO 2 -rich waters to the ocean surface. This process very likely dominated any biologically mediated CO 2 sequestration and probably accounts for most of the deglacial rise in atmospheric CO 2 .marine productivity | molecular biomarkers | paleoceanography

show abstract

Sources and fates of silicon in the ocean: the role of diatoms in the climate and glacial cycles

Cited by 35 publications

References 53 publications

Opal burial in the equatorial Atlantic Ocean over the last 30 ka: Implications for glacial‐interglacial changes in the ocean silicon cycle

Opal burial in the equatorial Atlantic Ocean over the last 30 ka: Implications for glacial‐interglacial changes in the ocean silicon cycle

Control of silica production by iron and silicic acid during the Southern Ocean Iron Experiment (SOFeX)

Eastern Equatorial Pacific productivity and related-CO ₂ changes since the last glacial period

Contact Info

Product

Resources

About

Sources and fates of silicon in the ocean: the role of diatoms in the climate and glacial cycles

Cited by 35 publications

References 53 publications

Opal burial in the equatorial Atlantic Ocean over the last 30 ka: Implications for glacial‐interglacial changes in the ocean silicon cycle

Opal burial in the equatorial Atlantic Ocean over the last 30 ka: Implications for glacial‐interglacial changes in the ocean silicon cycle

Control of silica production by iron and silicic acid during the Southern Ocean Iron Experiment (SOFeX)

Eastern Equatorial Pacific productivity and related-CO 2 changes since the last glacial period

Contact Info

Product

Resources

About

Eastern Equatorial Pacific productivity and related-CO ₂ changes since the last glacial period