Predicting soil physical and chemical properties using vis-NIR in Australian cotton areas

Abstract Management of Vertosols in southeast Australia, requires information about soil physical (e.g. particle size fractions) and chemical (e.g. cation exchange capacity [CEC – cmol(+) kg−1], exchangeable sodium percentage [ESP - %] and pH) properties. While visible and near-infrared (vis-NIR) spectroscopy calibration models have been developed, little has been done in Vertosols. The performance of multi-depth or depth-specific (i.e. topsoil [0–0.3 m], subsurface [0.3–0.6 m] and subsoil [0.9–1.2 m]) calibration models has also seldom been discussed. In this paper, using a spiking approach across seven cotton growing areas, our first aim was to determine which model (e.g. machine learning algorithm (Cubist) or partial least square regression with bootstrap aggregation [bagging-PLSR]) produced better calibrations using multi-depth data. The second aim was to see how these calibrations predict depth-specific soil properties using independent validation. Our third aim was to investigate whether depth-specific calibrations could produce better predictions. In terms of multi-depth calibration, exemplified by CEC, Cubist (R2 = 0.86) was stronger than bagging-PLSR (0.72). However, in terms of prediction agreement for independent validation, bagging-PLSR was superior to Cubist in the topsoil (LCCC = 0.84) and subsoil (0.83) and equivalent in the subsurface (0.74). Moreover, the depth-specific bagging-PLSR achieved equivelent prediction agreement for the independent validation of CEC to the multi-depth bagging-PLSR in the topsoil (LCCC = 0.85), subsoil (0.85) and subsurface (0.76). In terms of the other soil properties (i.e. clay, silt and sand), multi-depth bagging-PLSR was superior and overall a multi-depth spectral library is recommended for Vertosols. This has implications for acquiring a vis-NIR library more quickly and prediction efficiency with multi-depth calibrations.

[1]  Claudy Jolivet,et al.  Optimization criteria in sample selection step of local regression for quantitative analysis of large soil NIRS database , 2012 .

[2]  C. Hurburgh,et al.  Near-Infrared Reflectance Spectroscopy–Principal Components Regression Analyses of Soil Properties , 2001 .

[3]  Luis Alonso,et al.  Machine learning regression algorithms for biophysical parameter retrieval: Opportunities for Sentinel-2 and -3 , 2012 .

[4]  O. Mutanga,et al.  A comparison of partial least squares (PLS) and sparse PLS regressions for predicting yield of Swiss chard grown under different irrigation water sources using hyperspectral data , 2014 .

[5]  Viacheslav I. Adamchuk,et al.  A global spectral library to characterize the world’s soil , 2016 .

[6]  J. Triantafilis,et al.  Mapping cation exchange capacity using a quasi-3d joint inversion of EM38 and EM31 data , 2020 .

[7]  Jean-Michel Roger,et al.  Predictive ability of soil properties to spectral degradation from laboratory Vis-NIR spectroscopy data , 2017 .

[8]  R. V. Rossel,et al.  Visible and near infrared spectroscopy in soil science , 2010 .

[9]  Qinghu Jiang,et al.  Estimation of soil organic carbon and total nitrogen in different soil layers using VNIR spectroscopy: Effects of spiking on model applicability , 2017 .

[10]  B. Stenberg,et al.  Near‐infrared spectroscopy for within‐field soil characterization: small local calibrations compared with national libraries spiked with local samples , 2010 .

[11]  H. Beecher,et al.  The potential of near-infrared reflectance spectroscopy for soil analysis — a case study from the Riverine Plain of south-eastern Australia , 2002 .

[12]  L. Lin,et al.  A concordance correlation coefficient to evaluate reproducibility. , 1989, Biometrics.

[13]  André Carnieletto Dotto,et al.  Two preprocessing techniques to reduce model covariables in soil property predictions by Vis-NIR spectroscopy , 2017 .

[14]  John Triantafilis,et al.  A Vis-NIR Spectral Library to Predict Clay in Australian Cotton Growing Soil , 2018, Soil Science Society of America Journal.

[15]  A. Hartemink,et al.  Data fusion of vis–NIR and PXRF spectra to predict soil physical and chemical properties , 2019, European Journal of Soil Science.

[16]  José Janderson Ferreira Costa,et al.  Prediction of soil texture classes through different wavelength regions of reflectance spectroscopy at various soil depths , 2020 .

[17]  R. Zhao,et al.  Multi‐sensor fusion for the determination of several soil properties in the Yangtze River Delta, China , 2018, European Journal of Soil Science.

[18]  C. Guerrero,et al.  Near infrared spectroscopy for determination of various physical, chemical and biochemical properties in Mediterranean soils. , 2008, Soil biology & biochemistry.

[19]  Meiyan Wang,et al.  Comparison of multivariate methods for estimating selected soil properties from intact soil cores of paddy fields by Vis–NIR spectroscopy , 2018 .

[20]  Todd Sanderson,et al.  Near infrared diffuse reflectance spectroscopy for rapid and comprehensive soil condition assessment in smallholder cacao farming systems of Papua New Guinea , 2019, CATENA.

[21]  K. Shepherd,et al.  Global soil characterization with VNIR diffuse reflectance spectroscopy , 2006 .

[22]  L. Wilding,et al.  Spatial variability: its documentation, accommodation and implication to soil surveys , 1985 .

[23]  Philippe C. Baveye,et al.  Comment on "Potential of integrated field spectroscopy and spatial analysis for enhanced assessment of soil contamination: A prospective review" by Horta et al. , 2016 .