Arsenic-Imposed Effects on Schwertmannite and Jarosite Formation in Acid Mine Drainage and Coupled Impacts on Arsenic Mobility

Burton, Edward D; Karimian, Niloofar; Johnston, Scott G; Schoepfer, Valerie A.; Choppala, Girish; Lamb, Dane

doi:10.1021/acsearthspacechem.1c00047

Cited by 38 publications

(28 citation statements)

References 87 publications

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“…The Fe/S elemental relation and characteristic pincushion shape was coherent with early iron oxyhydroxysulfate schwertmannite (Fe 8 O 8 SO 4 (OH) 6 * nH 2 O) precipitate, which occasionally fossilized the preexisting microorganisms ( Figures 7A,B,E ). These particles showed incorporation of As, which is a common feature of this mineral ( Regenspurg and Peiffer, 2004 ; Burton et al, 2009 ; Burton et al, 2021 ). A higher Fe/S ratio and spherical, globular or idiomorphic crystals, with or without K, identified other iron particles as Fe hydroxysulfate jarosite (K/H 3 O + Fe 3 (SO 4 ) 2 (OH) 6 ; Figures 7B–D,F ).…”

Section: Resultsmentioning

confidence: 97%

“…It is widely reported that during the dissolution and recrystallization of schwertmannite, this mineral releases ionic species initially adsorbed onto the surface or in its’ structure ( Jones et al, 2006 ; Schoepfer and Burton, 2021 ; Zhang et al, 2022 ). On the one hand, the release of P ( Figure 5A ) to the interstitial space might be beneficial for the microbial growth in oligotrophic systems, but the release of As and Cd, commonly adsorbed onto schwertmannite and jarosite ( Burton et al, 2009 ; Burton et al, 2021 ), would be hazardous to the local ecosystem. From the biotechnological point of view, it is therefore crucial to balance the re-solubilization processes with SRB-mediated sulfide precipitation.…”

Section: Discussionmentioning

confidence: 99%

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Glycerol amendment enhances biosulfidogenesis in acid mine drainage-affected areas: An incubation column experiment

Ilin

Graaf

Yusta

et al. 2022

Front. Bioeng. Biotechnol.

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Microbial sulfate (SO42−) reduction in Acid Mine Drainage (AMD) environments can ameliorate the acidity and extreme metal concentrations by consumption of protons via the reduction of SO42− to hydrogen sulfide (H2S) and the concomitant precipitation of metals as metal sulfides. The activity of sulfate-reducing bacteria can be stimulated by the amendment of suitable organic carbon sources in these generally oligotrophic environments. Here, we used incubation columns (IC) as model systems to investigate the effect of glycerol amendment on the microbial community composition and its effect on the geochemistry of sediment and waters in AMD environments. The ICs were built with natural water and sediments from four distinct AMD-affected sites with different nutrient regimes: the oligotrophic Filón Centro and Guadiana acidic pit lakes, the Tintillo river (Huelva, Spain) and the eutrophic Brunita pit lake (Murcia, Spain). Physicochemical parameters were monitored during 18 months, and the microbial community composition was determined at the end of incubation through 16S rRNA gene amplicon sequencing. SEM-EDX analysis of sediments and suspended particulate matter was performed to investigate the microbially-induced mineral (neo)formation. Glycerol amendment strongly triggered biosulfidogenesis in all ICs, with pH increase and metal sulfide formation, but the effect was much more pronounced in the ICs from oligotrophic systems. Analysis of the microbial community composition at the end of the incubations showed that the SRB Desulfosporosinus was among the dominant taxa observed in all sulfidogenic columns, whereas the SRB Desulfurispora, Desulfovibrio and Acididesulfobacillus appeared to be more site-specific. Formation of Fe3+ and Al3+ (oxy)hydroxysulfates was observed during the initial phase of incubation together with increasing pH while formation of metal sulfides (predominantly, Zn, Fe and Cu sulfides) was observed after 1–5 months of incubation. Chemical analysis of the aqueous phase at the end of incubation showed almost complete removal of dissolved metals (Cu, Zn, Cd) in the amended ICs, while Fe and SO42− increased towards the water-sediment interface, likely as a result of the reductive dissolution of Fe(III) minerals enhanced by Fe-reducing bacteria. The combined geochemical and microbiological analyses further establish the link between biosulfidogenesis and natural attenuation through metal sulfide formation and proton consumption.

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Section: Resultsmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 99%

Glycerol amendment enhances biosulfidogenesis in acid mine drainage-affected areas: An incubation column experiment

Ilin

Graaf

Yusta

et al. 2022

Front. Bioeng. Biotechnol.

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“…These iron sulfate species in Mediterranean (Fitzpatrick et al 2017), tropical (Johnston et al 2010;Keene et al 2011;Johnston et al 2016), and subtropical (Ahern et al 2004;Claff et al 2010) regions have caused severe vegetation degradation by forming schwertmannite and/or akaganeite, two poorly crystalline Secondary Fe(III) phases (Shahabi-Ghahfarokhi et al 2022). Therefore, by using SCGs and HA, the formation of these problematic secondary iron species are potentially restricted by limiting the Fe and sulfate to form schwertmannite/akaganeite, often seen in sulfuric rich, acidic settings (Burton et al 2021;Shahabi-Ghahfarokhi et al 2022). However, the effects of simultaneous addition of SCGs and DHA should be further studied.…”

Section: Precipitationmentioning

confidence: 99%

Removal and Potential Recovery of Dissolved Metals from Acid Sulfate Soil Drainage by Spent Coffee-Grounds and Dissolved Organic Carbon

Shahabi-Ghahfarokhi

Rahmati-Abkenar²,

Matson³

et al. 2021

SSRN Journal

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“…Schwertmannite (Fe 16 O 16 (OH) 12 (SO 4 ) 2 ), a typical metastable secondary iron-hydroxysulfate mineral, is widespread in acidic sulfate environments such as acid mine drainage (AMD) or acid sulfate soils. − Schwertmannite plays an important role in immobilizing toxic metals due to its large specific surface area as well as abundant hydroxyl functional groups and structural sulfate for ligand exchange, − which exhibits a specific adsorption mechanism compared to other common iron oxides, such as ferrihydrite and goethite . For example, Cr(VI) is widely detected in AMD-polluted environments and could directly substitute sulfate through ligand–exchange reactions because these two anions possess the same charge and similar ionic radius .…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Interactions Occurring Between Cr(VI) and Citric Acid-Schwertmannite Composites: A Macroscopic and In Situ ATR-FTIR Study

Liang

et al. 2022

ACS Earth Space Chem.

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Organo-mineral composites play an important role in the mobility and bioavailability of toxic metals in natural environments. However, the interactions between heavy metals and composites remain ambiguous. In this study, citric acidschwertmannite (CA-Sch) composites were synthesized to investigate the interfacial behaviors of Cr(VI) adsorption via macroscopic experiments (adsorption kinetics, adsorption isotherms, and pH adsorption edge) coupled with in situ ATR-FTIR spectroscopy and XPS analysis. Macroscopic experimental results showed that the adsorption capacities and rate of Cr(VI) on CA-Sch composites presented a distinct decrease compared with those on Sch, wherein the former had a negative linear correlation with carbon loading content and the pH IEP of the composites. The structural sulfate and adsorbed CA could be substituted by Cr(VI) ions. In situ ATR-FTIR spectra of CA-Sch showed different responses after Cr(VI) adsorption, including a continuous release of structural sulfate and a slight weakening in the v as (COO − ) and v s (COO − ) of adsorbed CA, further revealing that Cr(VI) mainly coordinated to the CA-Sch composite surface via anion exchange with the tunnel structural sulfate, followed by an outer-sphere CA complex on the external surface. The coordination modes of Cr(VI) on the composite included monodentate (C 3v ) and bidentate (C 2v ) complexes. In addition, the analysis of element species content and XPS showed that partially adsorbed Cr(VI) on the CA-Sch composite was reduced to Cr(III) without being released into the solution. These findings advance our understanding of the interfacial behaviors of Cr(VI) on the CA-Sch composite surface and contribute to the evaluation of the fate of Cr(VI) in AMDcontaminated environments.

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Arsenic-Imposed Effects on Schwertmannite and Jarosite Formation in Acid Mine Drainage and Coupled Impacts on Arsenic Mobility

Cited by 38 publications

References 87 publications

Glycerol amendment enhances biosulfidogenesis in acid mine drainage-affected areas: An incubation column experiment

Glycerol amendment enhances biosulfidogenesis in acid mine drainage-affected areas: An incubation column experiment

Removal and Potential Recovery of Dissolved Metals from Acid Sulfate Soil Drainage by Spent Coffee-Grounds and Dissolved Organic Carbon

Investigation of the Interactions Occurring Between Cr(VI) and Citric Acid-Schwertmannite Composites: A Macroscopic and In Situ ATR-FTIR Study

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