Assessment of iron-based and calcium-phosphate nanomaterials for immobilisation of potentially toxic elements in soils from a shooting range berm
DATE:
2020-08-01
UNIVERSAL IDENTIFIER: http://hdl.handle.net/11093/6837
EDITED VERSION: https://linkinghub.elsevier.com/retrieve/pii/S0301479720305727
UNESCO SUBJECT: 2511.04 Química de Suelos ; 2303.18 Metales ; 3308.04 Ingeniería de la Contaminación
DOCUMENT TYPE: article
ABSTRACT
Shooting range facilities in military areas have been indicated as a hotspot of land degradation with high
contents of Potentially Toxic Elements (PTEs). Currently, based on the new nanomaterials with specific
characteristics, nanoremediation technologies are used to immobilise and to reduce the availability of
PTEs in field and laboratory conditions. In this study, the effects of nano-hydroxyapatite and/or hematite
on PTEs immobilisation (As, Cd, Cu, Pb, Sb and Zn) in military shooting range soils were assessed
through the measure of available and leachable forms with three single-extractions: calcium chloride
(0.01M CaCl2), low molecular weight organic acids (10mM LMWOAs) and toxicity characteristic
leaching procedure (TCLP). A sequential chemical extraction was used to determine the distribution of
the PTEs in the different geochemical phases of the soils before and after the nanomaterial treatments.
Results showed that the availability of PTEs decreased, especially for Pb (40-95%) and Zn (50-99%) after
nanomaterial treatments. When both nanomaterial (hydroxyapatite + hematite) were combined, the
immobilisation rate improved. However, when each nanomaterial was added individually to the soils,
some elements, such as, Cu or Sb, showed a slight increment of their mobilisation. The sequential
chemical extraction showed that the highest percentage of PTEs were mainly in the residual fraction
before and after adding nanomaterials, being even higher in soils after the nanomaterial treatments.
Likewise, the mobile fractions decreased after the treatment with nanomaterials. Our findings suggest that
nanoremediation techniques improve the soil conditions, but they should be used carefully to avoid
mobilisation of non-target PTEs or unexpected potentially impacts for soil biota
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