Soil Organic Carbon Content Prediction Using Soil-Reflected Spectra: A Comparison of Two Regression Methods

Sharon Gomes Ribeiro,Adunias dos Santos Teixeira,Luis Clenio Jario Moreira,Isabel Cristina da Silva Araújo,Marcio Regys Rabelo de Oliveira,Mirian Cristina Gomes Costa,Fernando Bezerra Lopes

doi:10.3390/rs13234752

Sharon Gomes Ribeiro, Adunias dos Santos Teixeira + Show 5 more

Open Access

https://doi.org/10.3390/rs13234752

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Journal: Remote sensing	Publication Date: Nov 24, 2021
Citations: 11	License type: CC BY 4.0

Affiliation: Universidade Federal do Ceará

Abstract

Quantifying the organic carbon content of soil over large areas is essential for characterising the soil and the effects of its management. However, analytical methods can be laborious and costly. Reflectance spectroscopy is a well-established and widespread method for estimating the chemical-element content of soils. The aim of this study was to estimate the soil organic carbon (SOC) content using hyperspectral remote sensing. The data were from soils from two localities in the semi-arid region of Brazil. The spectral reflectance factors of the collected soil samples were recorded at wavelengths ranging from 350–2500 nm. Pre-processing techniques were employed, including normalisation, Savitzky–Golay smoothing and first-order derivative analysis. The data (n = 65) were examined both jointly and by soil class, and subdivided into calibration and validation to independently assess the performance of the linear methods. Two multivariate models were calibrated using the SOC content estimated in the laboratory by principal component regression (PCR) and partial least squares regression (PLSR). The study showed significant success in predicting the SOC with transformed and untransformed data, yielding acceptable-to-excellent predictions (with the performance-to-deviation ratio ranging from 1.40–3.38). In general, the spectral reflectance factors of the soils decreased with the increasing levels of SOC. PLSR was considered more robust than PCR, whose wavelengths from 354 to 380 nm, 1685, 1718, 1757, 1840, 1876, 1880, 2018, 2037, 2042, and 2057 nm showed outstanding absorption characteristics between the predicted models. The results found here are of significant practical value for estimating SOC in Neosols and Cambisols in the semi-arid region of Brazil using VIS-NIR-SWIR spectroscopy.

Highlights

IntroductionSoil quality assessment includes the integration of physical, biological, and chemical properties as quality indicators [1]
It can be seen that the mean and median values for Soil Organic Carbon (SOC)—in the three data sets—are relatively close, suggesting that the central trend estimators are typical of a normal distribution [68]
The troughs shown between wavelengths from 450 nm to 950 nm in the mean spectral response of the samples collected in Area 2 (A2) may be related to the strong presence of different forms of iron, corroborating the results presented by various authors [52,71,90] who found the predominance of both amorphous and crystalline iron in Haplic Cambisols predominant in the region of A2

Summary

Introduction

Soil quality assessment includes the integration of physical, biological, and chemical properties as quality indicators [1]. As these key properties vary dynamically over space and time, such assessments represent a stimulating task for the academic community. Soil Organic Carbon (SOC) is recognised by farmers and scientists as a primary indicator of soil quality. Representing around 58% of the structure of organic matter (OM), SOC is considered the main carbon stock at the terrestrial level [2,3], with estimates of up to three times more C than are contained in the atmosphere [4].

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