2015
DOI: 10.1002/lom3.10028
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Alkaline‐extractable silicon from land to ocean: A challenge for biogenic silicon determination

Abstract: The biogeochemical cycling of silicon (Si) along the land-to-ocean continuum is studied by a variety of research fields and for a variety of scientific reasons. However, there is an increasing need to refine the methodology and the underlying assumptions used to determine biogenic silica (BSi) concentrations. Recent evidence suggests that contributions of nonbiogenic sources of Si dissolving during alkaline extractions, not corrected by standard silicate mineral dissolution correction protocols, can be substan… Show more

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Cited by 43 publications
(50 citation statements)
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“…Human activities such as deforestation, eutrophication, agriculture, and damming have altered weathering rates, amounts of terrestrial BSi production, and the amount of amorphous Si retained and/or released from soils and freshwater systems (Struyf et al, 2010). Our recent work demonstrates the gradual aggradation or depletion of the amorphous Si pool held in continental soils (Barão et al, 2015) and aquatic sediments (Frings et al, 2014) in response to changing environmental forcings (Struyf and Conley, 2012). Our emerging understanding is that DSi inputs from the continents have potentially altered the magnitude and isotopic composition to an extent great enough to impact wholeocean isotopic signatures on the timescale of Quaternary glacial cycles (Bernard et al, 2010).…”
Section: Oceanic Dsi During the Quaternarymentioning
confidence: 79%
“…Human activities such as deforestation, eutrophication, agriculture, and damming have altered weathering rates, amounts of terrestrial BSi production, and the amount of amorphous Si retained and/or released from soils and freshwater systems (Struyf et al, 2010). Our recent work demonstrates the gradual aggradation or depletion of the amorphous Si pool held in continental soils (Barão et al, 2015) and aquatic sediments (Frings et al, 2014) in response to changing environmental forcings (Struyf and Conley, 2012). Our emerging understanding is that DSi inputs from the continents have potentially altered the magnitude and isotopic composition to an extent great enough to impact wholeocean isotopic signatures on the timescale of Quaternary glacial cycles (Bernard et al, 2010).…”
Section: Oceanic Dsi During the Quaternarymentioning
confidence: 79%
“…Anthropogenic perturbations of the global biogeochemical Si cycle are due to the gradual aggradation or depletion of the amorphous SiO 2 pool held in continental soils (Barão et al, 2015;Vandevenne et al, 2015) and aquatic sediments (Frings et al, 2014b) in response to these changing environmental forcings (Struyf and Conley, 2012) and river damming (Conley et al, 1993). Our emerging understanding is that DSi inputs from the continents have potentially altered the magnitude and δ 30 Si composition of DSi supplied to the open ocean mostly because of changes occurring on the continent as well as changes of the silica sink on continental margins (Bernard et al, 2010;Frings et al, 2016).…”
Section: Global Si Cycle Over Timementioning
confidence: 99%
“…The k parameter reflects how fast a Si-bearing fraction reaches complete dissolution in an alkaline media, and depends on bonding strengths and specific reactive surface areas. Here, relative differences of k values between modelled fractions are used to classify high and low reactive fractions in alkaline media, where nanocrystalline and absorbed Si fractions are suggested to be more rapidly released as compared to biogenic Si fractions (Barão et al, 2015). The number of fractions (x) in the first-order model was determined by consecutively allowing an extra fraction to obtain an optimal model fit (i.e.…”
Section: Continuous Extraction Method: 05 M Naohmentioning
confidence: 99%
“…phytoliths, diatoms), inorganic forms such as Al-Si precipitates, volcanic glass shards, adsorbed Si on amorphous iron oxides, and nanocrystalline fractions such as allophanes and imogolite can comprise a substantial portion of the nonlinearly dissolving Si. Partial dissolution of clays can also rapidly release Si (Barão et al, 2015;Koning et al, 2002). We introduce a procedural term "Si Alk " (alkaline extracted Si) to refer to the full range of Si-bearing phases that dissolve non-linearly under normal experimental conditions.…”
Section: Introductionmentioning
confidence: 99%
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