Soils from an iron and steel scrap storage yard remediated with aided phytostabilization

Areas degraded by industrial activity demonstrate unfavorable chemical and physical conditions, including a high concentration of trace elements (TEs), which reduce the growth and development of appropriate plant cover. For the above reasons, in recent years, the demand for the development of natura...

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Bibliographic Details
Published in:Land degradation & development 2019-01, Vol.30 (2), p.202-211
Main Authors: Radziemska, Maja, Koda, Eugeniusz, Vaverkovà, Magdalena D., Gusiatin, Zygmunt M., Cerdà, Artemi, Brtnický, Martin, Mazur, Zbigniew
Format: Article
Language:English
Subjects:
Additives
aided phytostabilization
Alkaline soils
Bioavailability
Chemical activity
Chromium
Copper
Diatomaceous earth
Dolomite
Environmental protection
Immobilization
metal‐contaminated soil
New technology
Nickel
Organic chemistry
Phytotoxicity
risk minimization
Scrap iron
Soil amendment
Soil chemistry
Soil contamination
Soil pH
Soil pollution
Soil properties
soil reclamation
Soil remediation
Steel scrap
Trace elements
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Summary:Areas degraded by industrial activity demonstrate unfavorable chemical and physical conditions, including a high concentration of trace elements (TEs), which reduce the growth and development of appropriate plant cover. For the above reasons, in recent years, the demand for the development of natural and effective technologies for removing particularly hazardous compounds such as TEs from the environment has been growing. Because aided phytostabilization is a relatively new technology, examination of new additions immobilizing TEs in combination with an appropriately selected species plan poses a challenge in environmental protection and engineering. The novelty of this study is in the assessment of the usefulness of previously not applied soil amendments in processes of TEs immobilization in contaminated soils. This study presents the results of a vegetation experiment using a mix of grasses and rarely used mineral soil amendments (halloysite, diatomite, dolomite) for aided phytostabilization of soil originating from an area affected by industrial activity and characterized by high TEs concentrations. Additionally, the degree of phytotoxicity of the examined soils was determined. The greatest above‐ground biomass was observed when diatomite, dolomite, and halloysite were added to the soil. The concentrations of the analyzed TEs in test plants were higher in roots than in the above‐ground parts. This indicates that mineral amendments affected soil properties promoting TEs precipitation and decreasing TEs bioavailability. The highest increase in soil pH was observed after the application of dolomite to the soil. The average contents of Pb, Ni, Cu, and Cr in soil demonstrated the highest reduction after diatomite and halloysite application. The conducted research confirms the possibility of applying the examined soil additives to support phytostabilization of alkaline soil highly contaminated with TEs.
ISSN:1085-3278
1099-145X
DOI:10.1002/ldr.3215