Cosmogenic <sup>32</sup>Si as a tracer of biogenic silica burial and diagenesis: Major deltaic sinks in the silica cycle

Rahman, Shaily; Aller, Robert C.; Cochran, J. Kirk

doi:10.1002/2016gl069929

Cited by 55 publications

(73 citation statements)

References 47 publications

(85 reference statements)

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“…Thus the conservative estimates for the net storage of altered bSiO 2 and authigenic silicates in deltaic sediments range from 2-3x in the Mississippi (Presti and Michalopoulos, 2008) to 5-10x in the Amazon (Michalopoulos and Aller, 2004). Based on 32 Si, actual storage in the Amazon delta may be 2-3x greater (i.e., 3-4.5 Tmol yr −1 ) than the best recent conservative estimates (Rahman et al, 2016).…”

Section: Diagenetic Silica Precipitation and Reverse Weatheringmentioning

confidence: 89%

“…It has been proposed that reactive bSiO 2 that has undergone reconstitution/dissolution/reprecipitation transformations remains partially unaccounted for (Michalopoulos and Aller, 2004;Presti and Michalopoulos, 2008) using the traditional operational leach method of DeMaster (1981). However, measurements of cosmogenic 32 Si incorporated in reactive SiO 2 products indicate that even the modified alkaline leach methods used to date in high sediment accumulation rates underestimate the amount of reconstituted bSiO 2 and authigenic silicates stored in deltaic sediments (Rahman et al, 2016). Thus the conservative estimates for the net storage of altered bSiO 2 and authigenic silicates in deltaic sediments range from 2-3x in the Mississippi (Presti and Michalopoulos, 2008) to 5-10x in the Amazon (Michalopoulos and Aller, 2004).…”

Section: Diagenetic Silica Precipitation and Reverse Weatheringmentioning

confidence: 99%

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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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Section: Diagenetic Silica Precipitation and Reverse Weatheringmentioning

confidence: 89%

Section: Diagenetic Silica Precipitation and Reverse Weatheringmentioning

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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“…Since then diatom growth rates, sponge ages, and silica production rates in different areas have been estimated using this radionuclide as an introduced tracer (Blain et al, ; Brzezinski & Phillips, ; Smith et al, ; Kristiansen et al, , ; Brzezinski et al, ; Nelson et al, ; Rousseau et al, ; Sigmon et al, ; Ragueneau et al, ; Ellwood et al, ; Kemp & Villareal, ; Krause et al, ). Cosmogenic 32 Si at natural activity levels has recently been used to determine bSi opal and bSi clay storage (bSi clay ~0.4 Tmol/yr) in the Amazon delta‐Guianas mudbank dispersal system, suggesting that burial of bSi clay has been substantially underestimated in continental margins (Rahman et al, ).…”

Section: Introductionmentioning

confidence: 99%

The Missing Silica Sink: Revisiting the Marine Sedimentary Si Cycle Using Cosmogenic ³²Si

Rahman

Aller

Cochran

2017

Global Biogeochemical Cycles

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Burial of biogenic silica (bSitotal) in high sedimentation rate continental margins remains highly uncertain. Cosmogenic 32Si (t1/2~140 years) can be used to trace the fates of bSitotal postdeposition, including as opal (bSiopal) and diagenetically altered opal (bSialtered), the latter dominantly authigenic clay (bSiclay). To determine the magnitude and form of bSitotal storage in coastal sediments, conventional operational leaches targeting bSiopal and bSialtered (including bSiclay) were modified for large‐scale samples necessary for measurement of 32Si. The 32Si activity was used to estimate total biogenic silica burial (bSitotal = bSiopal + bSialtered) in several depositional settings: Gulf of Papua, Gulf of Mexico, Long Island Sound, and in the previously studied Amazon‐Guianas deltaic system. In subtropical and temperate regions, 32Si was detected in both traditional biogenic silica leaches (bSiopal) and residual authigenic clays. Traditional bSiopal and modified operational leaches designed to target the most reactive authigenic silicates (~bSialtered) consistently underestimate authigenic clay formation (bSiclay) and thus the magnitude of bSitotal burial in temperate coastal zones and subtropical deltas by 2–4‐fold. In tropical deltas, 32Si activities in the residual fraction after removal of bSiopal demonstrate rapid and almost complete alteration of initial bSiopal to new forms, most likely bSiclay. Globally, 4.5–4.9 Tmol/yr Si may be trapped in marine nearshore deposits as rapidly formed clay (bSiclay), 100% of the “missing silica sink” in the marine silica budget.

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“…The sources enter the ocean from rivers, meltwaters, groundwaters, as hydrothermal fluids and from the atmosphere (Tréguer and De La Rocha, 2013). The sinks include biosilicification and burial (Knoll, 2003) and the authigenesis of clay minerals (Mackenzie et al, 1967;Rahman et al, 2016).…”

Section: Biogeochemistry Of Silica In the Oceansmentioning

confidence: 99%

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

et al. 2017

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Biosilicification has driven variation in the global Si cycle over geologic time. The evolution of different eukaryotic lineages that convert dissolved Si (DSi) into mineralized structures (higher plants, siliceous sponges, radiolarians, and diatoms) has driven a secular decrease in DSi in the global ocean leading to the low DSi concentrations seen today. Recent studies, however, have questioned the timing previously proposed for the DSi decreases and the concentration changes through deep time, which would have major implications for the cycling of carbon and other key nutrients in the ocean. Here, we combine relevant genomic data with geological data and present new hypotheses regarding the impact of the evolution of biosilicifying organisms on the DSi inventory of the oceans throughout deep time. Although there is no fossil evidence for true silica biomineralization until the late Precambrian, the timing of the evolution of silica transporter genes suggests that bacterial silicon-related metabolism has been present in the oceans since the Archean with eukaryotic silicon metabolism already occurring in the Neoproterozoic. We hypothesize that biological processes have influenced oceanic DSi concentrations since the beginning of oxygenic photosynthesis.

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Cosmogenic ³²Si as a tracer of biogenic silica burial and diagenesis: Major deltaic sinks in the silica cycle

Cited by 55 publications

References 47 publications

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

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

The Missing Silica Sink: Revisiting the Marine Sedimentary Si Cycle Using Cosmogenic ³²Si

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

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Cosmogenic 32Si as a tracer of biogenic silica burial and diagenesis: Major deltaic sinks in the silica cycle

Cited by 55 publications

References 47 publications

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

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

The Missing Silica Sink: Revisiting the Marine Sedimentary Si Cycle Using Cosmogenic 32Si

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

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Product

Resources

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Cosmogenic ³²Si as a tracer of biogenic silica burial and diagenesis: Major deltaic sinks in the silica cycle

The Missing Silica Sink: Revisiting the Marine Sedimentary Si Cycle Using Cosmogenic ³²Si