Reducing conditions increased the mobilisation and hazardous effects of arsenic in a highly contaminated gold mine spoil

Arsenic (As) redox-induced mobilisation and speciation in polluted gold mine sites in tropical climates largely remains unknown. Here, we investigated the impact of changes in soil redox potential (EH) (−54 mV to +429 mV) on mobilisation of As and its dominant species in an abandoned spoil (total As...

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Bibliographic Details
Published in:Journal of hazardous materials 2022-08, Vol.436, p.129238-129238, Article 129238
Main Authors: Mensah, Albert Kobina, Marschner, Bernd, Wang, Jianxu, Bundschuh, Jochen, Wang, Shan-Li, Yang, Puu-Tai, Shaheen, Sabry M., Rinklebe, Jörg
Format: Article
Language:English
Subjects:
Flooding
Gold mining
Hazardous effects
Mobilization
Toxic elements
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Summary:Arsenic (As) redox-induced mobilisation and speciation in polluted gold mine sites in tropical climates largely remains unknown. Here, we investigated the impact of changes in soil redox potential (EH) (−54 mV to +429 mV) on mobilisation of As and its dominant species in an abandoned spoil (total As = 4283 mg/kg) using an automated biogeochemical microcosm set-up. Arsenic mobilisation increased (85–137 mg/L) at moderately reducing conditions (−54 mV to + 200 mV)), while its reduced (6–35 mg/L) under oxic conditions (+200 to +400 mV). This indicates the high risk of As potential loss under reducing conditions. The mobilisation of As was governed by the redox chemistry of Fe. XANES and EXAFS analyses showed that sorbed-As(V)-goethite, sorbed-As(III)-ferrihydrite, scorodite and arsenopyrite were the predominant As species in the mine spoil. As(V) dominated at oxic conditions and As(III) predominated at moderately reducing conditions, which may be attributed to either inability of arsenate bacteria to reduce As or incomplete reduction. Lower Fe/As molar ratios during moderately reducing conditions show that the mine spoil may migrate As to watercourses during flooding, which may increase the hazardous effects of this toxic element. Therefore, encouraging aerobic conditions may mitigate As release and potential loss from the mine field. [Display omitted] •As mobilisation in mine spoil was higher at low EH (200 mV).•As mobilisation was mainly governed by Fe chemistry.•As (V) in sediments persisted during moderately reducing conditions.•Lower Fe/As molar ratios at low EH show potential As migration to water.•As mitigation measures at the minefield should limit reducing conditions.
ISSN:0304-3894
1873-3336
DOI:10.1016/j.jhazmat.2022.129238