Leigh A Sullivan scite author profile

The rates of carbon bio-sequestration within silica phytoliths of the leaf litter of 10 economically important bamboo species indicates that (a) there is considerable variation in the content of carbon occluded within the phytoliths (PhytOC) of the leaves between different bamboo species, (b) this variation does not appear to be directly related to the quantity of silica in the plant but rather the efficiency of carbon encapsulation by the silica. The PhytOC content of the species under the experimental conditions ranged from 1.6% to 4% of the leaf silica weight. The potential phytolith carbon bio-sequestration rates in the leaf-litter component for the bamboos ranged up to 0.7 tonnes of carbon dioxide (CO 2 ) equivalents (t-e-CO 2 ) ha À1 yr À1 for these species. Assuming a median phytolith carbon bio-sequestration yield of 0.36 t-e-CO 2 ha À1 yr À1 , the global potential for bio-sequestration via phytolith carbon (from bamboo and/or other similar grass crops) is estimated to be $ 1.5 billion t-e-CO 2 yr À1 , equivalent to 11% of the current increase in atmospheric CO 2 . The data indicate that the management of vegetation such as bamboo forests to maximize the production of PhytOC has the potential to result in considerable quantities of securely bio-sequestered carbon.

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Schwertmannite transformation to goethite via the Fe(II) pathway: Reaction rates and implications for iron–sulfide formation

Burton

Bush

Sullivan

et al. 2008

Geochimica et Cosmochimica Acta

183

144

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Sorption of Arsenic(V) and Arsenic(III) to Schwertmannite

Burton

Bush

Johnston

et al. 2009

Environ. Sci. Technol.

244

134

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This study describes the sorption of As(V) and As(III) to schwertmannite as a function of pH and arsenic loading. In general, sorption of As(V) was greatest at low pH, whereas high pH favored the sorption of As(III). The actual pH of equivalent As(V) and As(III) sorption was strongly loading dependent, decreasing from pH approximately 8.0 at loadings <120 mmol(As) mol(Fe)(-1) to pH approximately 4.6 at a loading of 380 mmol(As) mol(Fe)(-1). Sorption isotherms for As(V) were characterized by strong partitioning to the schwertmannite solid-phase at low loadings and sorption capacities of 225-330 mmol(As(V)) mol(Fe)(-1) at high loadings. In contrast, the As(III) isotherms revealed a weak affinity for sorption of As(III) versus As(V) at low loadings yet a greater affinity for As(III) sorption compared with As(V) at high loadings (when pH > 4.6). Sorption of As(V) and As(III) caused significant release of SO(4)(2-) from within the schwertmannite solid-phase, without major degradation of the schwertmannite structure (as evident by X-ray diffraction and Raman spectroscopy). This can be interpreted as arsenic sorption via incorporation into the schwertmannite structure, rather than merely surface complexation at the mineral-water interface. The results of this study have important implications for arsenic mobility in the presence of schwertmannite, such as in areas affected by acid-mine drainage and acid-sulfate soils. In particular, arsenic speciation, arsenic loading, and pH should be considered when predicting and managing arsenic mobility in schwertmannite-rich systems.

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Mobility of arsenic and selected metals during re-flooding of iron- and organic-rich acid-sulfate soil

et al. 2008

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Leigh A Sullivan

Soil carbon sequestration in phytoliths

Carbon bio‐sequestration within the phytoliths of economic bamboo species

Schwertmannite transformation to goethite via the Fe(II) pathway: Reaction rates and implications for iron–sulfide formation

Sorption of Arsenic(V) and Arsenic(III) to Schwertmannite

Mobility of arsenic and selected metals during re-flooding of iron- and organic-rich acid-sulfate soil

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