The role of soluble Fe(III) in the cycling of iron and sulfur in coastal marine sediments

Carey, Elizabeth A.; Taillefert, Martial

doi:10.4319/lo.2005.50.4.1129

Cited by 47 publications

(34 citation statements)

References 53 publications

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“…FeS and aqueous inorganic S species), and the actual in-situ rates is consistent with several previous studies of pyrite formation in more complex systems. For example, Canfield et al (1998), Carey and Taillefert (2005) and Burton et al (2007) all found that pyrite formation in complex systems (ferrihydrite/bacteria suspensions, estuarine sediments, and Fe(III)-rich soils, respectively) exceeded theoretical rates by several orders of magnitude.…”

Section: Comparison Between the Observed And Theoretical Rates Of Pyrmentioning

confidence: 96%

Sulfur biogeochemical cycling and novel Fe–S mineralization pathways in a tidally re-flooded wetland

Burton

Bush

Johnston

et al. 2011

Geochimica et Cosmochimica Acta

147

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Section: Comparison Between the Observed And Theoretical Rates Of Pyrmentioning

confidence: 96%

Sulfur biogeochemical cycling and novel Fe–S mineralization pathways in a tidally re-flooded wetland

Burton

Bush

Johnston

et al. 2011

Geochimica et Cosmochimica Acta

147

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“…The voltammetric conditions used in triplicate cathodic square wave voltammetry (CSWV) measurements included preconditioning at Ϫ0.9 V for 10 s and deposition at Ϫ0.1 V for 10 s to concentrate Fe(III) species at the electrode surface. A scan rate of 200 mV s Ϫ1 from Ϫ0.1 to Ϫ1.8 V with a pulse height of 0.05 V was used as previously described (10,59,60,62 ) by CSWV in degassed medium, and the pilot ion method was used to quantify concentrations of Fe(II). Voltammograms were integrated using a semiautomated software program developed for these applications (6).…”

mentioning

confidence: 99%

Siderophores Are Not Involved in Fe(III) Solubilization during Anaerobic Fe(III) Respiration by Shewanella oneidensis MR-1

Fennessey

Jones

Taillefert

et al. 2010

Appl Environ Microbiol

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“…The extensive presence of iron oxides across the Satilla River estuary (not shown) suggests that both processes may have been responsible for the production of these complexes in the sediment. FeS (aq) was detected in the transition zone between iron and sulfate reduction in over 60% of the profiles that contain dissolved sulfides, indicating that iron was chemically precipitated by sulfide in these sediments (Taillefert et al 2002;Carey and Taillefert 2005). Although sediment diagenesis in estuarine sediments typically transitions from manganese and iron reduction (Aller 1980) or even methanogenesis (Martens and Goldhaber 1978) to sulfate reduction along salinity gradients, manganese and iron reduction were significant in most sediments along the Satilla River during the 3 yr of this study.…”

Section: Discussionmentioning

confidence: 96%

The effect of riverine discharge on biogeochemical processes in estuarine sediments

Meiggs

Taillefert

2011

Limnology & Oceanography

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A recently developed autonomous benthic lander equipped with an underwater potentiostat and a micromanipulator for in situ voltammetric depth profiling of main redox species in pore waters was deployed for 3 yr at multiple stations along the Satilla River estuary (Georgia, U.S.A.). These measurements revealed that biogeochemical processes in estuarine sediments vary seasonally and are influenced by riverine discharge. A prolonged drought decreased river discharge, altered the salinity gradient in the estuary, and profoundly affected anaerobic respiratory processes in the underlying sediments. Under normal hydrologic conditions, iron reduction was the dominant anaerobic respiratory process across the estuary, likely due to the significant supply of iron from the coastal plane and low salinity of the estuary. Under drought conditions, the salinity of the estuary increased to full seawater strength and carbon remineralization was enhanced significantly. Yet, sulfate reduction was only observed near the mouth of the estuary, whereas a substantial increase in iron reduction was distinctive upriver. Evidence indicates that the increase in iron-reducing activity during the drought resulted mainly from the deposition of mineral particles in the upper estuary when the salinity gradient increased. Altogether, this study demonstrates that the biogeochemical response of estuarine sediments to natural perturbations is rapid and that respiration processes are controlled by a combination of temperature, supply of inorganic and organic substrates, and hydrological processes. These findings also suggest that an increase in the frequency of droughts as a result of climate change may enhance the resiliency of iron-reducing bacteria in river-fed estuarine sediments.

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The role of soluble Fe(III) in the cycling of iron and sulfur in coastal marine sediments

Cited by 47 publications

References 53 publications

Sulfur biogeochemical cycling and novel Fe–S mineralization pathways in a tidally re-flooded wetland

Sulfur biogeochemical cycling and novel Fe–S mineralization pathways in a tidally re-flooded wetland

Siderophores Are Not Involved in Fe(III) Solubilization during Anaerobic Fe(III) Respiration by Shewanella oneidensis MR-1

The effect of riverine discharge on biogeochemical processes in estuarine sediments

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