Potential of integrated field spectroscopy and spatial analysis for enhanced assessment of soil contamination: A prospective review

Publication date: March 2015
Source:Geoderma, Volumes 241–242
Author(s): A. Horta , B. Malone , U. Stockmann , B. Minasny , T.F.A. Bishop , A.B. McBratney , R. Pallasser , L. Pozza
There are tens of millions of contaminated soil sites in the world, and with an increasing population and associated risk there is a growing pressure to remediate them. A barrier to remediation is the lack of cost-effective approaches to assessment. Soil contaminants include a wide range of natural and synthetic metallic and organic compounds and minerals thus making analytical costs potentially very large. Further, soil contaminants show a large degree of spatial variation which increases the burden on sampling costs. This paper reviews potentially cost-effective methods for measurement, sampling design, and assessment. Current tiered investigation approaches and sampling strategies can be improved by using new technologies such as proximal sensing. Design of sampling can be aided by on-the-go proximal soil sensing; and expedited by subsequent adaptive spatially optimal sampling and prediction procedures enabled by field spectroscopic methods and advanced geostatistics. Field deployment of portable Visible & Near Infrared [wavelength 400–2500nm] (Vis-NIR) and X-ray fluorescence (PXRF) spectroscopies will require special calibration approaches but show huge potential for synergistic use. The use of mid-infrared spectroscopy [wavelength 2500–25,000nm, wavenumber 4000–400cm⁻¹] (MIR) for field implementation requires further adaptive research. We propose an integrated field-deployable methodology as a basis for further developments.