Biosilicification Drives a Decline of Dissolved Si in the Oceans through Geologic Time

Conley, Daniel J.; Frings, Patrick J.; Fontorbe, Guillaume; Clymans, Wim; Stadmark, Johanna; Hendry, Katharine R.; Marron, Alan O.; Rocha, Christina L. De La

doi:10.3389/fmars.2017.00397

Cited by 102 publications

(94 citation statements)

References 172 publications

(297 reference statements)

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“…Diatoms were likely key players in the ocean Si cycle in the Early Cenozoic (Conley et al, 2017; Renaudie et al, 2018), so we can use insights from the modern ocean to guide our interpretations. Today, sea surface δ 30 Si is primarily driven by diatom Si uptake and precipitation of their frustules.…”

Section: Discussionmentioning

confidence: 99%

Constraints on Earth System Functioning at the Paleocene‐Eocene Thermal Maximum From the Marine Silicon Cycle

Fontorbe

Frings

Rocha³

et al. 2020

Paleoceanog and Paleoclimatol

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The Paleocene-Eocene Thermal Maximum (PETM, ca. 56 Ma) is marked by a negative carbon isotope excursion (CIE) and increased global temperatures. The CIE is thought to result from the release of 13 C-depleted carbon, although the source(s) of carbon and triggers for its release, its rate of release, and the mechanisms by which the Earth system recovered are all debated. Many of the proposed mechanisms for the onset and recovery phases of the PETM make testable predictions about the marine silica cycle, making silicon isotope records a promising tool to address open questions about the PETM. We analyzed silicon isotope ratios (δ 30 Si) in radiolarian tests and sponge spicules from the Western North Atlantic (ODP Site 1051) across the PETM. Radiolarian δ 30 Si decreases by 0.6‰ from a background of 1‰ coeval with the CIE, while sponge δ 30 Si remains consistent at 0.2‰. Using a box model to test the Si cycle response to various scenarios, we find the data are best explained by a weak silicate weathering feedback, implying the recovery was mostly driven by nondiatom organic carbon burial, the other major long-term carbon sink. We find no resolvable evidence for a volcanic trigger for carbon release, or for a change in regional oceanography. Better understanding of radiolarian Si isotope fractionation and more Si isotope records spanning the PETM are needed to confirm the global validity of these conclusions, but they highlight how the coupling between the silica and carbon cycles can be exploited to yield insight into the functioning of the Earth system.

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Section: Discussionmentioning

confidence: 99%

Constraints on Earth System Functioning at the Paleocene‐Eocene Thermal Maximum From the Marine Silicon Cycle

Fontorbe

Frings

Rocha³

et al. 2020

Paleoceanog and Paleoclimatol

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“…The global silicon (Si) cycle is of great interest due to the role that silicate weathering has played in maintaining climatic stability on geological time scales (Siever, 1991;Frings et al, 2016;Conley et al, 2017) and because Si is an important nutrient for many organisms in marine and freshwater ecosystems. It occurs as silicate minerals in association with all rock types (igneous, metamorphic, sedimentary).…”

Section: Introductionmentioning

confidence: 99%

“…Weathering, biological and geochemical transformations, transport and interactions with other elements (in particular nutrients and carbon) form the basis of the global biogeochemical Si cycle . The global Si cycle has evolved through geologic time with overall declines in oceanic dissolved Si due to the uptake and deposition by organisms (Siever, 1991;Conley et al, 2017). While the modern Si biogeochemical cycle is influenced by anthropogenic forcing (Laruelle et al, 2009), the processes of weathering and burial as biogenic silica (bSiO 2 ) are the dominant processes in the biogeochemical Si cycle.…”

Section: Introductionmentioning

confidence: 99%

A Review of the Stable Isotope Bio-geochemistry of the Global Silicon Cycle and Its Associated Trace Elements

et al. 2018

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“…Recent studies have robustly demonstrated the presence of very low oceanic silicic acid concentrations since at least 60 Ma, most likely as a result of the drawdown of silicic acid by diatom biomineralization (Fontorbe et al, 2016, which is tens of millions of years before the time period envisioned by Siever (1991) and others. Conley et al (2017) have hypothesized that if such a global decrease in oceanic silicic acid concentrations Sims et al, 2006;Fontorbe et al, 2016Fontorbe et al, , 2017 Diatoms and sponges Post-Mesozoic decline of certain sponge spicule morphologies Maldonado et al, 1999 Diatoms and radiolarians; Diatoms and silicoflagellates Silicificaton and shell-thickness/spine morphology, decline of radiolarians in the low latitudes throughout the Cenozoic (reason still debated) Lazarus et al, 2009;van Tol et al, 2012;Cermeño et al, 2015 Ecology in modern oceans…”

Section: Evolutionary Competition Across Geological Timementioning

confidence: 99%

“…The nature of this competition has changed over geological time in conjunction with changes in the biogeochemical cycling of silicon (Racki and Cordey, 2000;Maliva et al, 2005;Finkel and Kotrc, 2010;Knoll and Kotrc, 2015;Conley et al, 2017). In turn, this is reflected in the evolutionary molecular biology of silicon transport mechanisms.…”

Section: Cellular and Molecular Aspects Of Evolutionary Competitionmentioning

confidence: 99%

Competition between Silicifiers and Non-silicifiers in the Past and Present Ocean and Its Evolutionary Impacts

et al. 2018

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Competition is a central part of the evolutionary process, and silicification is no exception: between biomineralized and non-biomineralized organisms, between siliceous and non-siliceous biomineralizing organisms, and between different silicifying groups. Here we discuss evolutionary competition at various scales, and how this has affected biogeochemical cycles of silicon, carbon, and other nutrients. Across geological time we examine how fossils, sediments, and isotopic geochemistry can provide evidence for the emergence and expansion of silica biomineralization in the ocean, and competition between silicifying organisms for silicic acid. Metagenomic data from marine environments can be used to illustrate evolutionary competition between groups of silicifying and non-silicifying marine organisms. Modern ecosystems also provide examples of arms races between silicifiers as predators and prey, and how silicification can be used to provide a competitive advantage for obtaining resources. Through studying the molecular biology of silicifying and non-silicifying species we can relate how they have responded to the competitive interactions that are observed, and how solutions have evolved through convergent evolutionary dynamics.

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Biosilicification Drives a Decline of Dissolved Si in the Oceans through Geologic Time

Cited by 102 publications

References 172 publications

Constraints on Earth System Functioning at the Paleocene‐Eocene Thermal Maximum From the Marine Silicon Cycle

Constraints on Earth System Functioning at the Paleocene‐Eocene Thermal Maximum From the Marine Silicon Cycle

A Review of the Stable Isotope Bio-geochemistry of the Global Silicon Cycle and Its Associated Trace Elements

Competition between Silicifiers and Non-silicifiers in the Past and Present Ocean and Its Evolutionary Impacts

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