Abstract
Treatment with chemical amendments is among the best techniques to remediate soils highly polluted with trace elements. The use of waste-derived products has several advantages in this regard, mainly in terms of reducing process costs and conserving natural resources. In this study, the performance of the synthetic zeolite NaP1 derived from coal combustion fly ash (SZ) and the by-product generated from the processing of aluminum salt slags (BP) was evaluated with this aim in comparison to calcite (CC). For this purpose, mine soils polluted with Zn, Cd, and Pb were amended under controlled laboratory conditions with different doses (0%, 1%, 2%, 5%, and 10%) of SZ, BP, or CC, and their impact on trace element mobility and microbial functions was evaluated. Specifically, the mobile and mobilizable trace element pools, basal soil respiration, and different enzyme activities were analyzed. Both SZ and BP performed better than CC in the immobilization of trace elements, reaching, respectively, mobility decreases up to 89–94% and 66–87% when applied at a dose of 10%. These amendments reduced the mobile trace element pool by precipitating them as acid-soluble precipitates and/or retaining them in the reducible fraction of soils. The alkaline nature of these materials and the concomitant increase in soil pH caused by their application mainly accounted for this behavior. Additionally, soil microbial functionality improved after amendment, especially in the case of SZ, as shown by dehydrogenase and alkaline phosphatase activities, which significantly increased (p < 0.05) up to 536% and 48%, respectively. Therefore, applying SZ or BP as soil amendments can significantly decrease the mobile trace element contents of heavily polluted soils without negatively affecting soil quality, thus facilitating plant growth to revegetate and reclaim degraded spaces.
Highlights
Soil contamination is one of the main causes of soil degradation
The performance of the synthetic zeolite NaP1 derived from coal combustion fly ash (SZ) and the by-product generated from the processing of aluminum salt slags (BP) was evaluated with this aim in comparison to calcite (CC)
The alkaline character of these materials and the concomitant increase in soil pH provoked after their application mainly accounted for this behavior
Summary
Soil contamination is one of the main causes of soil degradation. Soil contamination with trace elements is a serious issue due to the non-biodegradability and persistence of these contaminants. Many of them are considered highly toxic and readily avail able. Of these, mining activities, not the largest emitting source, are considered one of the most highly polluting, severely impacting the soils of the mine setting and surrounding area. Soil trace element concentrations as high as several thousand above their normal levels in non-contaminated soils have been found quite frequently in this type of emplacement (Bech et al, 2012). Increased soil trace element content significantly affects soil quality and poses a huge risk of transfer to other environmental compartments (Lwin et al, 2018)
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