Leaching of arsenic, copper and chromium from thermally treated soil

Leaching of arsenic, copper and chromium from thermally treated soil

Thermal treatment, if properly performed, is an effective way of destroying organic compounds in contaminated soil, while impact on co-present inorganic contaminants varies depending on the element. Leaching of trace elements in thermally treated soil can be altered by co-combusting different types...

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Bibliographic Details
Published in:Journal of environmental management Vol. 183; no. Pt 3; pp. 460 - 466
Main Authors: Kumpiene, Jurate, Nordmark, Désirée, Hamberg, Roger, Carabante, Ivan, Simanavičienė, Rūta, Aksamitauskas, Vladislovas Česlovas
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-12-2016
Academic Press Ltd
Subjects:
Arsenic - analysis
Arsenic - chemistry
Avfallsteknik
Chromium - analysis
Chromium - chemistry
Coal
Coal Ash - chemistry
Combustion
Contaminated soil
Copper - analysis
Copper - chemistry
Environmental Restoration and Remediation - methods
EXAFS
Fly ash
Inorganic chemistry
Iron - chemistry
Leaching
Soil - chemistry
Soil contamination
Soil Pollutants - analysis
Soil Pollutants - chemistry
Spectrum analysis
Temperature effects
Trace elements
Waste Products
Waste Science and Technology
Wood - chemistry
X-Ray Absorption Spectroscopy
Combustion
Contaminated soil
Leaching
EXAFS
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Summary:Thermal treatment, if properly performed, is an effective way of destroying organic compounds in contaminated soil, while impact on co-present inorganic contaminants varies depending on the element. Leaching of trace elements in thermally treated soil can be altered by co-combusting different types of materials. This study aimed at assessing changes in mobility of As, Cr and Cu in thermally treated soil as affected by addition of industrial by-products prior to soil combustion. Contaminated soil was mixed with either waste of gypsum boards, a steel processing residue (Fe3O4), fly ash from wood and coal combustion or a steel abrasive (96.5% Fe0). The mixes and unamended soil were thermally treated at 800 °C and divided into a fine fraction <0.125 mm and a coarse fraction >0.125 mm to simulate particle separation occurring in thermal treatment plants. The impact of the treatment on element behaviour was assessed by a batch leaching test, X-ray absorption spectroscopy and dispersive X-ray spectrometry. The results suggest that thermal treatment is highly unfavourable for As contaminated soils as it increased both the As leaching in the fine particle size fraction and the mass of the fines (up to 92%). Soil amendment with Fe-containing compounds prior to the thermal treatment reduced As leaching to the levels acceptable for hazardous waste landfills, but only in the coarse fraction, which does not justify the usefulness of such treatment. Among the amendments used, gypsum most effectively reduced leaching of Cr and Cu in thermally treated soil and could be recommended for soils that do not contain As. Fly ash was the least effective amendment as it increased leaching of both Cr and As in majority of samples. •Thermal treatment increases arsenic leaching in soil.•Leaching of copper and chromium is low in thermally treated soil.•Metal(loid) leaching can be modified by soil amendments prior to thermal treatment.
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ISSN:0301-4797
1095-8630
1095-8630
DOI:10.1016/j.jenvman.2016.08.080