Soil-pH and cement influence the weathering kinetics of chrysotile asbestos in soils and its hydroxyl radical yield

Chrysotile asbestos is a toxic and carcinogenic mineral that has been used in a variety of industrial and consumer applications. Much of the fiber- and cement-containing asbestos waste has ended up in terrestrial environments. Chrysotile weathering in soils and the potential for natural attenuation...

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Bibliographic Details
Published in:Journal of hazardous materials 2022-06, Vol.431, p.128068-128068, Article 128068
Main Authors: Walter, Martin, Geroldinger, Gerald, Gille, Lars, Kraemer, Stephan M., Schenkeveld, Walter D.C.
Format: Article
Language:English
Subjects:
Asbestos
Asbestos, Serpentine - chemistry
Environmental persistence
Hydrogen-Ion Concentration
Hydroxyl Radical
Kinetics
Mineral weathering
Remediation
Soil
Soil pollution
Tetrahedral Fe
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Summary:Chrysotile asbestos is a toxic and carcinogenic mineral that has been used in a variety of industrial and consumer applications. Much of the fiber- and cement-containing asbestos waste has ended up in terrestrial environments. Chrysotile weathering in soils and the potential for natural attenuation have, however, hardly been examined yet. Here we explored how soil properties influence the dissolution rate of chrysotile, the release of the carcinogenic metals chromium and nickel, and the hydroxyl radical (HO•) generation by chrysotile fibers. Chrysotile dissolution rates in soil suspensions decreased with increasing soil-pH and were lower than reported rates in soil-free systems. Dissolved organic carbon did not markedly accelerate dissolution at circumneutral pH, whereas cement mixed with soil inhibited dissolution because of its alkalinity. The HO•-yield of incubated fibers in non-amended soils eventually decreased by 60–75%. The decline was fastest in an acidic podzol soil, yet was followed by a small rebound. Cement amendment induced the largest HO•-yield reduction (∼90%), presumably due to surface coating of the fibers. Overall, this work demonstrates that the potential for natural attenuation of chrysotile asbestos in soils critically depends on soil chemical parameters and the presence of cement in association with the fibers. [Display omitted] •Chrysotile asbestos dissolution rate decreased with increasing soil pH.•No dissolution of chrysotile asbestos was observed in cement amended soil.•Hydroxyl radical yield of chrysotile decreased by ≈ 60 – 75% in non-amended soils.•Cement amendment further lowered the fibers’ radical yield in soil.
ISSN:0304-3894
1873-3336
DOI:10.1016/j.jhazmat.2021.128068