Abstract

Soils are essential for supporting food production and providing ecosystem services but are under pressure due to population growth, higher food demand, and land use competition. Because of the effort to ensure the sustainable use of soil resources, demand for current, updatable soil information capable of supporting decisions across scales is increasing. Digital soil mapping (DSM) addresses the drawbacks of conventional soil mapping and has been increasingly used for delivering soil information in a time- and cost-efficient manner with higher spatial resolution, better map accuracy, and quantified uncertainty estimates. We reviewed 244 articles published between January 2003 and July 2021 and then summarised the progress in broad-scale (spatial extent >10,000 km2) DSM, focusing on the 12 mandatory soil properties for GlobalSoilMap. We observed that DSM publications continued to increase exponentially; however, the majority (74.6%) focused on applications rather than methodology development. China, France, Australia, and the United States were the most active countries, and Africa and South America lacked country-based DSM products. Approximately 78% of articles focused on mapping soil organic matter/carbon content and soil organic carbon stocks because of their significant role in food security and climate regulation. Half the articles focused on soil information in topsoil only (<30 cm), and studies on deep soil (100–200 cm) were less represented (21.7%). Relief, organisms, and climate were the three most frequently used environmental covariates in DSM. Nonlinear models (i.e. machine learning) have been increasingly used in DSM for their capacity to manage complex interactions between soil information and environmental covariates. Soil pH was the best predicted soil property (average R2 of 0.60, 0.63, and 0.56 at 0–30, 30–100, and 100–200 cm). Other relatively well-predicted soil properties were clay, silt, sand, soil organic carbon (SOC), soil organic matter (SOM), SOC stocks, and bulk density, and coarse fragments and soil depth were poorly predicted (R2 < 0.28). In addition, decreasing model performance with deeper depth intervals was found for most soil properties. Further research should pursue rescuing legacy data, sampling new data guided by well-designed sampling schemas, collecting representative environmental covariates, improving the performance and interpretability of advanced spatial predictive models, relating performance indicators such as accuracy and precision to cost-benefit and risk assessment analysis for improving decision support; moving from static DSM to dynamic DSM; and providing high-quality, fine-resolution digital soil maps to address global challenges related to soil resources.

Highlights

  • We reviewed 244 articles on the use of Digital soil mapping (DSM) to map GlobalSoilMap soil properties at a broad scale (>10,000 km2) published from January 2003 to July 2021

  • (2) Many articles do not provide information on how the soil sample data were collected, such as sampling year and sampling strategy. We suggest that this information should be reported because of its high relevance to DSM quality and the design of future sampling campaigns

  • (3) Most of the studies focused on mapping soil organic carbon (SOC)/soil organic matter (SOM), SOC stocks, and soil particle size fractions

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Summary

Background

In the 21st century, the world is experiencing grand challenges, such as large population increases, food security, land degradation, fresh­ water scarcity, threatened biodiversity, climate change, and sustainable development (FAO, 2011). These soil maps are difficult to interpret and use for decisionmaking in land management (Sanchez et al, 2009) because they are mostly based on taxonomic classification rather than quantifying soil properties In response to these challenges, digital soil mapping (DSM, McBratney et al, 2003) has emerged over the last two decades to predict soil properties by integrating soil survey data, geographic information systems, geostatistics, terrain analysis, machine learning, remote sensing, and high-performance computing (Minasny and McBratney, 2016; Arrouays et al, 2017a). S refers to soil information; c refers to climate; o refers to organisms, vegetation, fauna or human activity; r refers to relief; p refers to parent material; a refers to age or time factor; n refers to spatial or geographic position; and e are spatially correlated residuals Most of these variables are spatially and temporally explicit

Scientific activity
Methods
Frequency of articles per year and journal
Spatial distribution of articles
Soil sampling
Soil property and maximum depth of interest
Environmental covariates and spatial resolution of map products
Predictive models
Model performance of soil properties
GlobalSoilMap products
Current trends
How to use legacy data and acquire new soil information?
Spatial modelling and prediction
Performance evaluation uncertainty estimation and map resolution
Findings
Conclusions

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