Assessment of mercury pollution sources in beach sand and coastal soil by speciation analysis

Gallego, José Luis; López-Antón, M. Antonia; Rosa, Deva Martínez de la; Rodríguez-Valdés, Eduardo; García-González, Nerea; Rodríguez, Edgar Charry; Martı́nez-Tarazona, M. Rosa

doi:10.1186/s12302-019-0264-3

Cited by 12 publications

(2 citation statements)

References 42 publications

(48 reference statements)

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“…The study was completed with the identification of mercury species in the untreated and treated soils directly using a mercury temperature programmed desorption (HgTPD) device [35]. The device, previously described [36], consists of a temperature-programed furnace coupled to a PYRO 915 furnace from LUMEX and a continuous mercury analyzer (RA-915). Desorption profiles are obtained by heating the sample at a rate of 50 °C min −1 .…”

Section: Hg Speciation and Sequential Extractionmentioning

confidence: 99%

Immobilization of mercury in contaminated soils through the use of new carbon foam amendments

et al. 2021

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Background Mercury (Hg) is recognized as one of the 10 most toxic elements in nature and is much more persistent in soils than in other environmental compartments. However, an effective, environmentally friendly, economical, and large-scale applicable technology for the remediation of soils contaminated by Hg has not yet been established. This study evaluates the feasibility of a new carbon foam-based product for the remediation of three soils contaminated with Hg, and infers the mobilization or immobilization mechanism through a detailed study of Hg speciation. Results Soil treatment with carbon foams, one of them impregnated with goethite, reduced Hg availability by 75–100%. The proportion of mercury associated to humic acids (Hg–HA) determined the mobility and the availability of Hg when soils were treated with carbon foams. The drop of pH promotes changes in the structure of HA, a consequence of which is that Hg–HA becomes part of the unavailable fraction of the soil along with HgS. The carbon foam impregnated with goethite did not mobilize Fe as occurred with zero valence iron nanoparticles. The presence of acidic groups on the surface of the foam (carboxyl, quinone and phenolic groups) can strongly improve the binding of metal cations, enhancing Fe immobilization. Conclusions A novel carbon foam-based amendment was efficient in immobilizing Hg in all the soils studied. The carbon foam impregnated with goethite, in addition to not mobilizing Fe, had the additional advantage of its low effect on the electrical conductivity of the soil. This novel approach could be considered as a potential amendment for other industrial and/or abandoned mining areas contaminated with Hg and/or other metal(loid)s.

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Section: Hg Speciation and Sequential Extractionmentioning

confidence: 99%

Immobilization of mercury in contaminated soils through the use of new carbon foam amendments

et al. 2021

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“…The study was completed with the identification of mercury species in the untreated and treated soils directly by desorption at programmed temperature using a mercury temperature programmed desorption (HgTPD) device [33]. The device previously described [34] consists of a temperature-programed furnace coupled to a PYRO 915 furnace from LUMEX and a continuous mercury analyzer (RA-915). Desorption profiles are obtained by heating the sample at a rate of 50 °C min -1 .…”

Section: Hg Speciation and Sequential Extractionmentioning

confidence: 99%

Immobilization of mercury in contaminated soils through the use of new carbon foam amendments

Janeiro-Tato

López-Antón

Baragaño

et al. 2021

Preprint

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Background: Mercury (Hg) is recognized as one of the 10 most toxic elements and is much more persistent in soils than in other environmental compartments. However, an effective, environmentally friendly, economical, and applicable at large-scale technology for the remediation of soils contaminated by Hg has not yet been established. This study evaluates the feasibility of a new carbon foam-based product for the remediation of three soils contaminated with Hg, and infers the mobilization or immobilization mechanism through a detailed study of Hg speciation. Results: Soil treatment with the carbon foams, one of them impregnated with goethite, reduced Hg availability by between 75 and 100%. Mercury associated to humic acid (Hg-HA) determined the proportion of mobility and availability of Hg when soils were treated with carbon foams. When the pH dropped, the structure of HA changed causing the Hg-HA to become part of the unavailable fraction of the soil along with HgS. The carbon foam impregnated with goethite did not mobilize Fe as occurred with ZVI nanoparticles. The presence of acid groups on the surface of the foam (carboxyl, quinone and phenolic groups) can bind metal cations strongly improving Fe immobilization. Conclusions: A novel carbon foam-based amendment was efficient in immobilizing Hg in all the soils studied. The carbon foam impregnated with goethite, in addition to not mobilizing Fe, had the additional advantage of its lesser effect on the electrical conductivity of the soil. This novel approach could be considered as a potential amendment for other sites contaminated with Hg and/or other metal(loid)s.

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Characteristics of soil contamination by potentially toxic elements in mine areas of Mongolia

Yoon,

Kim,

et al. 2023

Environ Geochem Health

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Assessment of mercury pollution sources in beach sand and coastal soil by speciation analysis

Cited by 12 publications

References 42 publications

Immobilization of mercury in contaminated soils through the use of new carbon foam amendments

Immobilization of mercury in contaminated soils through the use of new carbon foam amendments

Immobilization of mercury in contaminated soils through the use of new carbon foam amendments

Characteristics of soil contamination by potentially toxic elements in mine areas of Mongolia

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