Abstract
While traditional laboratory methods of determining soil organic carbon (SOC) content are generally simple, this becomes more challenging when carbonates are present in the soil; such is commonly found in semi-arid areas. Additionally, soil inorganic carbon (SIC) content itself is difficult to determine. This study uses visible near infrared (VisNIR) spectra to predict SOC and SIC contents of samples, and the impact of including soil pH and soil total carbon (STC) data as predictor variables was evaluated. The results indicated that combining available soil pH and STC content data with VisNIR spectra dramatically improved prediction accuracy of the Cubist models. Using the full suite of predictor variables, Cubist models trained on the calibration dataset (75%) could predict the validation dataset (25%) for SOC content with a Lin’s concordance correlation coefficient (LCCC) of 0.94, and an LCCC of 0.83 for SIC content. This is compared to an LCCC of 0.81 and 0.35 for SOC and SIC content, respectively, when no ancillary soil data was included with VisNIR spectra as predictor variables. These results suggest that there may be promise for using other readily available soil data in combination with VisNIR spectra to improve the predictions of different soil properties.•It can be laborious and expensive to measure soil organic and inorganic carbon content with traditional laboratory methods, and there has been recent focus on using spectroscopic techniques to overcome this.•This study demonstrates that combining ancillary soil data (pH and total carbon content) with these spectroscopic techniques can considerably improve predictions of SOC and SIC content.
Highlights
The University of Sydney, School of Life and Environmental Sciences, Sydney Institute of Agriculture, Sydney, New South Wales, Australia
Visible near infrared (VisNIR) spectroscopy predictions. Both soil organic carbon (SOC) and soil inorganic carbon (SIC) content of samples displayed a mild to strong relationship (Pearson’s correlation) with the predictor variables of soil total carbon (STC) content and soil pH (Table 2)
SOC content was predicted with very high accuracy by the model that included visible near infrared (VisNIR), mid-depth, pH and STC, with an Lin’s concordance correlation coefficient (LCCC) of 0.94 when predicted on the validation dataset compared to an LCCC of 0.81 for the model that contained only VisNIR and mid-depth
Summary
This study uses soil data collected from a semi-arid area surrounding the township of Hillston, in south-west NSW. The study area is $2500 km in size, and primarily consists of largely flat alluvial floodplains, with some rocky outcrops at higher elevation. The soils on the floodplain are mainly grey, brown and red Vertisols (IUSS Working Group WRB 2014), with sandier soils of largely aeolian origin at the higher points. Soil samples from 80 locations from a soil survey conducted in 2002 are used, as well as 140 soil cores from a soil survey from 2015 [5]. Samples were extracted from soils under a variety of land uses, including irrigated and dryland cropping, irrigated perennial horticulture, and rangeland grazing. The soil dataset consists of 399 soil samples
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