Abstract
Soil contamination by potentially toxic elements (PTEs) is intensifying under increasing industrialization. Thus, the ability to efficiently delineate contaminated sites is crucial. Visible–near infrared (vis–NIR: 350–2500 nm) and X-ray fluorescence (XRF: 0.02–41.08 keV) spectroscopic techniques have attracted tremendous attention for the assessment of PTEs. Recently, the application of fused vis–NIR and XRF spectroscopy, which is based on the complementary effect of data fusion, is also increasing. Moreover, different data manipulation methods, including feature selection approaches, affect the prediction performance. This study investigated the feasibility of using single and fused vis–NIR and XRF spectra while exploring feature selection algorithms for the assessment of key soil PTEs. The soil samples were collected from one of the most heavily polluted areas of the Czech Republic and scanned using laboratory vis–NIR and XRF spectrometers. Univariate filter (UF) and genetic algorithm (GA) were used to select the bands of greater importance for the PTE prediction. Support vector machine (SVM) was then used to train the models using the full-range and feature-selected spectra of single sensors and their fusion. It was found that XRF spectra alone (primarily GA-selected) performed better than single vis–NIR and fused spectral data for predictions of PTEs. Moreover, the prediction models that were derived from the fused data set (particularly the GA-selected) enhanced the models’ accuracies as compared with the single vis–NIR spectra. In general, the results suggest that the GA-selected spectra obtained from the single XRF spectrometer (for As and Pb) and from the fusion of vis–NIR and XRF (for Pb) are promising for accurate quantitative estimation detection of the mentioned PTEs.
Highlights
The soil science society of America (SSSA) defines soil contaminant as any substance in soil that exceeds naturally-occurring levels and poses human health risks
The results showed that: (i) when using the full-range data of individual sensors, X-ray fluorescence (XRF) predicted all potentially toxic elements (PTEs) with an R2 larger than 0.71, which is better than the results that were obtained from Visible– near infrared (vis–NIR); (ii) the predictions obtained from the sensors’ fused data set enhanced the models’ accuracies, when compared with the use of solely vis–NIR
The single XRF data set provided better results than the fused spectra in the majority of the examined PTEs; (iii) the use of the genetic algorithm (GA) method improved the estimation accuracies of As and Pb models as compared with the full-range spectra using either single or fused spectra; (iv) the escalating impact of feature selection on prediction performance was more pronounced for the individual vis–NIR spectra as compared with the XRF and fused spectra; and (v) Pb was the most accurately predicted element using all of the examined data sets with confidence in the individual and fused vis–NIR and XRF spectra
Summary
The soil science society of America (SSSA) defines soil contaminant as any substance in soil that exceeds naturally-occurring levels and poses human health risks. As a major group of soil contaminants, potentially toxic elements (PTEs) (e.g., As, Pb, Cd, and Cr ) can be primarily found in soluble and adsorbed fractions [3]. These elements can present risks to animal and human health by entering the food chain, water, soil, and plants [4,5]. Their persistent nature and long biological half-lives disturb the soil balance and threaten the health of animals and plants, which reduces the seed quality and root growth of some species [6,7]. Assessing PTE concentrations in soil is of particular interest for their effective monitoring and further remediation
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