Removal of Arsenic, Boron, and Selenium from Excavated Rocks by Consecutive Washing

Tabelin, Carlito Baltazar; Basri, Amir Hamzah Mohd; Igarashi, Toshifumi; Yoneda, Tetsuro

doi:10.1007/s11270-012-1181-x

Cited by 50 publications

(8 citation statements)

References 35 publications

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“…Similarly, Krysiak and Karczewska have found that during the extraction of soils from Złoty Stok with Ca(NO 3 ) 2 at a pH < 2, intensive dissolution of Fe oxides occurred, and subsequently As was removed in a more soluble form. Arsenic mobility in soil is strongly limited by its high adsorption affinity for Fe/Al‐oxyhydroxides/oxides and clay minerals like kaolinite . By lowering the pH, protons can promote dissolution of arsenopyrite and/or metal oxide .…”

Section: Resultsmentioning

confidence: 99%

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Fe‐modified Clinoptilolite is Effective to Recover Plant Biosurfactants Used for Removing Arsenic From Soil

Gusiatin

2015

CLEAN Soil Air Water

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The aim of this study was to determine the effect of the biosurfactant concentration, pH, and extraction time on arsenic (As) removal from brownfield soils by saponin (SAP), and tannic acid (TA). Sandy loam (soil 1) and silt loam (soil 2) soils containing 7598.4 and 4294.2 mg As/kg, respectively, were tested. After washing, the effluents were treated with clinoptilolite modified with FeCl 3 and then their ability to remove As was compared with the control biosurfactant solutions. Removal of As increased gradually as SAP and TA concentration increased (0.005-5%). Arsenic was more efficiently removed under acidic (pH 2-3) than alkaline conditions (pH 9-11). The distribution of As in soils affected the length of extraction time. A pseudo-second-order kinetic model gave a good fit for kinetic data for both biosurfactants. The efficiency of As removal depended on the soil and biosurfactant type. Under optimized conditions (3% SAP and TA, pH 3, 24 h extraction), As removal from soil 1 and 2 was 27 and 46% with SAP and 5 and 39% with TA, respectively. Modified clinoptilolite at a dosage of 300 g/L removed !80% of As from SAP and TA effluents. Although the reused biosurfactants did not extract As as effectively as the original solutions, pH adjustment improved their effectiveness.

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Section: Resultsmentioning

confidence: 99%

“…By lowering the pH, protons can promote dissolution of arsenopyrite and/or metal oxide . Moreover, an acidic pH prevents the precipitation of dissolved Fe as Fe‐oxyhydroxides/oxides . This can explain the reason of enhancing the removal of Fe at low pH values.…”

Section: Resultsmentioning

confidence: 99%

Fe‐modified Clinoptilolite is Effective to Recover Plant Biosurfactants Used for Removing Arsenic From Soil

Gusiatin

2015

CLEAN Soil Air Water

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“…Mining, mineral processing and tunnel/underground construction for roads and railways often generate large amounts of wastes that contain sulfide minerals such as pyrite (FeS 2 ) and arsenopyrite (FeAsS), which produce acid mine drainage (AMD) when exposed to the environment [1][2][3][4][5][6][7][8][9][10][11][12][13][14]. AMD is very acidic and could further extract heavy metals (e.g., Fe, Cu, Zn, and Pb) from other minerals found in the wastes.…”

Section: Introductionmentioning

confidence: 99%

“…In the first CME study of Satur et al [21], titanium (Ti)-catechol complex was synthesized by mixing TiO 2 minerals (rutile and anatase) and pyrocatechol (1,2-dihydroxybenzene). These authors showed that although catechol could extract 6 Ti-ions from TiO 2 directly, extraction efficiency was very low. CME was also successfully applied to suppress pyrite oxidation in this previous study but the mechanism(s) involved remained unclear because the authors mixed TiO 2 and catechol together with pyrite.…”

Section: Introductionmentioning

confidence: 99%

Suppression of the release of arsenic from arsenopyrite by carrier-microencapsulation using Ti-catechol complex

Tabelin

Magaribuchi

Seno

et al. 2018

Journal of Hazardous Materials

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Arsenopyrite is the most common arsenic-bearing sulfide mineral in nature, and its weathering contributes to acid mine drainage (AMD) formation and the release of toxic arsenic (As). To mitigate this problem, carrier-microencapsulation (CME) using titanium (Ti)-catechol complex (i.e., Ti-based CME) was investigated to passivate arsenopyrite by forming a protective coating. Ti ion dissolved in sulfuric acid and catechol were used to successfully synthesize Ti(IV) tris-catecholate complex, [Ti(Cat)], which was stable in the pH range of 5-12. Electrochemical studies on the redox properties of this complex indicate that its oxidative decomposition was a one-step, irreversible process. The leaching of As from arsenopyrite was suppressed by CME treatment using the synthesized Ti-catechol complex. Scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDX) and diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) indicate that this suppression was primarily due to the formation of an anatase (β-TiO)-containing coating. Based on these results, a detailed 4-step mechanism to explain the decomposition of [Ti(Cat)] and formation of TiO coating in Ti-based CME is proposed: (1) adsorption, (2) partial oxidation-intermediate formation, (3) non electrochemical dissociation, and (4) hydrolysis-precipitation.

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“…Like other heavy metals and metalloids, mercury toxicity is closely related to its chemical form (i.e. methylmercury is more toxic than metallic/ionic mercury), while its mobility is strongly dependent on its solid-phase partitioning with different mineral phases in sediments and soils (Bakir et al, 1973; Millán et al, 2006; Tabelin et al, 2012a, 2012b). One of the most commonly used methods to determine the solid-phase partitioning of mercury is sequential extraction, a technique that involves treatment of the sample with a series of solvents that specifically attack certain minerals in the sample matrix (e.g.…”

Section: Introductionmentioning

confidence: 99%

Solid-phase partitioning of mercury in artisanal gold mine tailings from selected key areas in Mindanao, Philippines, and its implications for mercury detoxification

et al. 2018

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The solid-phase partitioning of mercury could provide necessary data in the identification of remediation techniques in contaminated artisanal gold mine tailings. This study was conducted to determine the total mercury content of mine wastes and identify its solid-phase partitioning through selective sequential extraction coupled with cold vapor atomic absorption spectroscopy. Samples from mine tailings and carbon-in-pulp (CIP) process were obtained from selected key areas in Mindanao, Philippines. The results showed that mercury use is still prevalent among small-scale gold miners in the Philippines. Tailings after ball mill-gravity concentration (W-BM and Li-BM samples) from Mt.Diwata and Libona contained high levels of mercury amounting to 25 and 6.5 mg/kg, respectively.The most prevalent form of mercury in the mine tailings was elemental/amalgamated mercury, followed by water soluble, exchangeable, organic, and strongly-bound phases, respectively. In contrast, mercury content of CIP residues were significantly lower at only 0.3 and 0.06 mg/kg for P-CIP (Del Pilar) and W-CIP (Mt. Diwata), respectively. The bulk of mercury in P-CIP samples was partitioned in residual fraction while in W-CIP sample, water soluble mercury predominated. Overall, this study has several important implications with regards to mercury detoxification of contaminated mine tailings from Mindanao, Philippines.

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Removal of Arsenic, Boron, and Selenium from Excavated Rocks by Consecutive Washing

Cited by 50 publications

References 35 publications

Fe‐modified Clinoptilolite is Effective to Recover Plant Biosurfactants Used for Removing Arsenic From Soil

Fe‐modified Clinoptilolite is Effective to Recover Plant Biosurfactants Used for Removing Arsenic From Soil

Suppression of the release of arsenic from arsenopyrite by carrier-microencapsulation using Ti-catechol complex

Solid-phase partitioning of mercury in artisanal gold mine tailings from selected key areas in Mindanao, Philippines, and its implications for mercury detoxification

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