Biogenic opal diagenesis in sediments. Biogenic opal What is it? Amorphous silica: (~ 10% water)

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Presentation transcript:

Biogenic opal diagenesis in sediments

Biogenic opal What is it? Amorphous silica: (~ 10% water)

Biogenic opal What is it? Amorphous silica: (~ 10% water) Measurement: Leach solid in Na 2 CO 3 ; make a correction for detrital Si

Biogenic opal What is it? Amorphous silica: (~ 10% water) Precipitated in the surface ocean by: -- phytoplankton diatoms, silicoflagellates -- protozoans radiolaria

Biogenic opal What is it? Amorphous silica: (~ 10% water) Precipitated in the surface ocean by: -- phytoplankton diatoms, silicoflagellates -- protozoans radiolaria A fraction fall of this opal falls to the sea floor -- it’s efficiently recycled, in water column and sediments -- overall, ~ 3% of opal production is preserved in sediments

Biogenic opal What is it? Amorphous silica: (~ 10% water) Biogenic opal is soluble in seawater, Si(OH) 4 is a weak acid, pK ~9 ==> it’s mostly protonated in seawater

Si(OH) 4 distribution in the ocean Depleted in surface waters, enriched in deep water Highest concentrations: deep NE Pacific ** All conc. < 200 µM

The solubility of biogenic opal in seawater Initial Studies -- Hurd, 1973, GCA 37, Experiment: -- separate opal from cores -- clean with acid -- place in sw at controlled temp After ~ days:

The solubility of biogenic opal in seawater Initial Studies -- Hurd, 1973, GCA 37, Experiment: -- separate opal from cores -- clean with acid -- place in sw at controlled temp After ~ days: Note: T dependence Solubility ~ 900 µM at 2°C !

Note: There is also a moderate pressure dependence of opal solubility… Calculated from molar volume data:

The kinetics of biogenic opal dissolution in seawater Hurd, 1972, EPSL 15, (log scale)

A mineral, undersaturated in seawater apparently simple dissolution kinetics… What do we expect [Si(OH) 4 ] in pore water to look like?

… and that is what’s observed … sort of…

Comparing asymptotic pore water [Si(OH) 4 ] to the “equilibrium” value

Explaining the discrepancy between the aymptotic and apparent equilibrium values… A rate law for opal dissolution:

Explaining the discrepancy between the aymptotic and apparent equilibrium values… A rate law for opal dissolution: Explanation I : It’s a kinetic phenomenon: k i B i --> 0 with increasing depth in the sediments

Explaining the discrepancy between the aymptotic and apparent equilibrium values… A rate law for opal dissolution: Explanation II : Solubility (C equil ) varies from place to place Proposal: a) Opal solubility depends on Al/Si in the opal b) Al is released by minerals during diagenesis, then substitutes for Si in opal

Explaining the discrepancy between the aymptotic and apparent equilibrium values… A rate law for opal dissolution: Explanation III: The rate law above is incomplete… In addition, there is reprecipitation of Si(OH) 4 as authigenic aluminosilicate

On Explanation II: Dependence of solubility on Al/Si in diatom tests van Bennekom et al., 1988, Paleo 3 67, Batch-dissolution experiments: diatoms from different regions in sw

On Explanation II: Dependence of solubility on Al/Si in diatom tests van Bennekom et al., 1988, Paleo 3 67, Batch-dissolution experiments: diatoms from different regions in sw Both dissolution rate and asymptotic value decrease as Al content of test increases

On Explanation II: Dependence of solubility on Al/Si in diatom tests van Bennekom et al., 1988, Paleo 3 67, And added to these results: Al/Si ratio in diatoms vs. [Si(OH)4] in surrounding pore waters: Squares: data from previous plot; Closed circles: diatoms from sediment / pore water SiO 2

A study of opal diagenesis in the Southern Ocean (Indian Ocean sector) van Cappellen and Qiu, 1997,DSRII 44, Dixit et al., 2001, Mar Chem 73,

New solubility studies : Flow-through reactors -- add solid sample to solution of known composition in reactor: “biosiliceous ooze” -- continually pump solution of known composition through reactor: 0.7M NaCl, buffered at pH 8 with tris, HCl; + variable Si(OH) 4 -- monitor composition of outflow - especially Si(OH) 4

New solubility studies: Flow-through reactors V = volume C = conc of solute M = conc of solute R = reaction rate C R, F … at steady state… So

Results Example of one experiment

Results Example of one experiment T dependence of solubility - KTB06 Conc. In outflow water Filled: precipitation Open: dissolution

Results Example of one experiment T dependence of solubility - KTB06 Compare to other studies: … correcting for surface area Circles: plankton Bars: variable Al/Si Squares: cultures

Results: Apparent solubility differences within and between cores

~ 25% diff in asymptotic conc Apparent sol -- indistinguishable

Another factor… Al in pore waters Asymptotic conc depends systematically on det/opal ratio Maximum Al in pore waters Depends on % detrital

Further studies 1. Effect of Al on solubility Southern ocean sediments, cm ; measure Al/Si ratio; determine solubility (note: Al/Si in diatoms found to covary with % detrital of sediments) Result: significant effect but not enough to explain all asymptotic SiO2 variation

Further studies 2. Experiment on effect of %det/%opal on equilibrium Si(OH) 4 Mix detrital material and biogenic opal in variable proportions; observe the dissolved Si(OH) 4 At steady state Detrital material: (a) kaolinite -- Al 2 Si 2 (OH) 4 (b) basalt (48.5 wt% SiO 2 ; 14.4 wt % Al 2 O 3 21-month batch experiments

Further studies 2. Experiment on effect of %det/%opal on equilibrium Si(OH) 4 Mix detrital material and biogenic opal in variable proportions; observe the dissolved Si(OH) 4 At steady state Detrital material: (a) kaolinite -- Al 2 Si 2 (OH) 4 (b) basalt (48.5 wt% SiO 2 ; 14.4 wt % Al 2 O 3 21-month batch experiments Dependence of steady-state Si(OH) 4 on det/opal ratio significantly greater than Al/Si effect on solubility

Further studies 3. Are authigenic aluminosilicates precipitating? Experiment: flow through reactors, containting 50 mg “biosiliceous ooze” Inflow: 500 nM Al, variable Si(OH )4

Further studies 3. Are authigenic aluminosilicates precipitating? Experiment: flow through reactors, containting 50 mg “biosiliceous ooze” Inflow: 500 nM Al, variable Si(OH )4 No SiO 2 in inflow: high Al in outflow Highest SiO 2 in inflow : lowest Al in outflow ==> removal of Al(III) from solution When Si(OH) 4 is present

A proposed mechanism Processes: Dissolution of biogenic silica release of Al from detrital minerals Incorporation of Al into opal decreases its solubility authigenic aluminosilicate formation Asymptotic SiO 2 between the 2 solubilities; value depends on relative rates

Addendum… similar results from other places Gallinari et al., 2002, GCA 66, % det / %opal = 26.. But small difference between apparent sol. and asymp SiO 2 … reprecipitation is Important in reactors as well as In sediments

Addendum… solubility depends on properties of biogenic opal, too Batch experiments, similar to those described earlier…