Correcting field determination of elemental contents in soils via portable X-ray fluorescence spectrometry

Thaís Santos Branco Dijair,Nilton Curi,Fernanda Magno Silva,Sérgio Henrique Godinho Silva,Luiz Roberto Guimarães Guilherme,Anita Fernanda Dos Santos Teixeira

doi:10.1590/1413-7054202044002420

Thaís Santos Branco Dijair, Nilton Curi + Show 4 more

Open Access

https://doi.org/10.1590/1413-7054202044002420

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Journal: Ciência e Agrotecnologia	Publication Date: Jan 1, 2020
Citations: 11	License type: CC BY 4.0

Affiliation: Universidade Federal de Lavras

Abstract

ABSTRACT Portable X-ray fluorescence (pXRF) spectrometry has been useful worldwide for determining soil elemental content under both field and laboratory conditions. However, the field results are influenced by several factors, including soil moisture (M), soil texture (T) and soil organic matter (SOM). Thus, the objective of this work was to create linear mathematical models for conversion of Al2O3, CaO, Fe, K2O, SiO2, V, Ti and Zr contents obtained by pXRF directly in field to those obtained under laboratory conditions, i.e., in air-dried fine earth (ADFE), using M, T and SOM as auxiliary variables, since they influence pXRF results. pXRF analyses in field were performed on 12 soil profiles with different parent materials. From them, 59 samples were collected and also analyzed in the laboratory in ADFE. pXRF field data were used alone or combined to M, T and SOM data as auxiliary variables to create linear regression models to predict pXRF ADFE results. The models accuracy was assessed by the leave-one-out cross-validation method. Except for light-weight elements, field results underestimated the total elemental contents compared with ADFE. Prediction models including T presented higher accuracy to predict Al2O3, SiO2, V, Ti and Zr, while the prediction of Fe and K2O contents was insensitive to the addition of the auxiliary variables. The relative improvement (RI) in the prediction models were greater in predictions of SiO2 (T+SOM: RI=22.29%), V (M+T: RI=18.90%) and Ti (T+SOM: RI=11.18%). This study demonstrates it is possible to correct field pXRF data through linear regression models.

Highlights

X-ray fluorescence is a technique capable of providing quantitative data on the content of chemical elements in the analyzed material (Potts; West, 2008)
The higher the quartz content in the parent material the smaller the soil clay content, which is associated with the high quartz resistance to weathering mostly present in the sand particle size fraction
The elemental/oxides contents obtained by Portable X-ray fluorescence (pXRF) in field soil analysis and under laboratory conditions varied for all analyzed elements/oxides

Summary

Introduction

X-ray fluorescence is a technique capable of providing quantitative data on the content of chemical elements in the analyzed material (Potts; West, 2008). This technique has been used in different branches of science, such as geochemistry, archeology, forensic science and soil science (Ribeiro et al, 2017; Weindorf; Bakr; Zhu, 2014). In this technique, a source of energy that emits X-rays hit the atoms of the analyzed material, making electrons to move from inner to outer orbits. The intensity of the fluorescence detected determines the content of that element in the sample (Weindorf; Bakr; Zhu, 2014)

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