Fingerprinting sedimentary and soil units by their natural metal contents: A new approach to assess metal contamination

One of the major issues when assessing soil contamination by inorganic substances is reliable determination of natural metal concentrations. Through integrated sedimentological, pedological and geochemical analyses of 1414 (topsoil/subsoil) samples from 707 sampling stations in the southern Po Plain...

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Bibliographic Details
Published in:The Science of the total environment 2014-12, Vol.500-501, p.361-372
Main Authors: Amorosi, Alessandro, Guermandi, Marina, Marchi, Nazaria, Sammartino, Irene
Format: Article
Language:English
Subjects:
Alluvial plain
Chromium
Concentration (composition)
Environmental Monitoring - methods
Geochemical map
Geochemistry
Geologic Sediments - chemistry
Mathematical analysis
Metal pollution
Metals - analysis
Metals - standards
Natural background
Nickel
Po Plain
Soil (material)
Soil - chemistry
Soil contamination
Soil Pollutants - analysis
Soil Pollutants - standards
Texture
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Summary:One of the major issues when assessing soil contamination by inorganic substances is reliable determination of natural metal concentrations. Through integrated sedimentological, pedological and geochemical analyses of 1414 (topsoil/subsoil) samples from 707 sampling stations in the southern Po Plain (Italy), we document that the natural distribution of five potentially toxic metals (Cr, Ni, Cu, Zn and Pb) can be spatially predicted as a function of three major factors: source-rock composition, grain size variability and degree of soil weathering. Thirteen genetic and functional soil units (GFUs), each reflecting a unique combination of these three variables, are fingerprinted by distinctive geochemical signatures. Where sediment is supplied by ultramafic (ophiolite-rich) sources, the natural contents of Cr and Ni in soils almost invariably exceed the Italian threshold limits designated for contaminated lands (150mg/kg and 120mg/kg, respectively), with median values around twice the maximum permissible levels (345mg/kg for Cr and 207mg/kg for Ni in GFU B5). The original provenance signal is commonly confounded by soil texture, with general tendency toward higher metal concentrations in the finest-grained fractions. Once reliable natural metal concentrations in soils are established, the anthropogenic contribution can be promptly assessed by calculating metal enrichments in topsoil samples. The use of combined sedimentological and pedological criteria to fingerprint GFU geochemical composition is presented here as a new approach to enhance predictability of natural metal contents, with obvious positive feedbacks for legislative purposes and environmental protection. Particularly, natural metal concentrations inferred directly from a new type of pedogeochemical map, built according to the international guideline ISO 19258, are proposed as an efficient alternative to the pre-determined threshold values for soil contamination commonly established by the national regulations. •Sedimentary facies and soil units are fingerprinted by their natural metal contents.•Source-rock composition, grain size and soil weathering control metal distribution.•Background concentrations of Cr and Ni commonly exceed the Italian guidelines.•Predetermined background values are inadequate to depict local pollution.•Geochemical maps based on soil/geological data allow assessing metal contamination.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2014.08.078