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RESEARCH ARTICLE

Creating a soil parent material map digitally using a combination of interpretation and statistical techniques

Ho Jun Jang https://orcid.org/0000-0001-7461-9955 A B , Mercedes Roman Dobarco A , Budiman Minasny A and Alex McBratney A
+ Author Affiliations
- Author Affiliations

A School of Life and Environmental Sciences, The University of Sydney, NSW 2006, Australia.

B Corresponding author. Email: hojun.jang@sydney.edu.au

Soil Research 59(7) 684-698 https://doi.org/10.1071/SR20212
Submitted: 1 August 2020  Accepted: 24 February 2021   Published: 19 May 2021

Abstract

In this study, a map of soil parent material is created to support the delineation of soil properties and classes of the Narrabri Shire, NSW. Currently, available information in this study area is geological and lithological maps at a scale of 1:250 000 to 1:1 000 000. These maps are not detailed, and the description in some areas is not accurate. Thus, this study created a new parent material map using information from the geological and lithology information, barest earth satellite imagery, gamma radiometric, topography, prior soil map and digital soil texture maps (clay and sand content). Based on interpretation and parent material observations, 18 parent material classes were delineated in the area. The 18 classes were then modelled using Linear Discriminant Analysis using Digital Elevation Model, slope, topographic wetness index, Gamma potassium (K) and thorium (Th), Ratio K to Th and soil visible and near infrared (NIR) reflectance (created using RGB and NIR bands) as covariates. This modelling process was iterated 50 times, and the most frequently predicted class was assigned to each of the 90 m × 90 m pixels throughout the study area. A map of the frequency of the predicted classes was also created to assess modelling uncertainty. The new parent material map consists of sedimentary residuals (sandstone), volcanic materials (basalt), alluvium and colluvium. The alluvium can be distinguished into six classes according to slope, soil information from satellite images and soil texture. The colluvium consists of three classes with a characteristic of high clay content (smectitic) and brown in colour (kaolinitic). Using similar approaches, such soil parent material or substrate maps could be developed for different regions in Australia. This method generated unique soil parent material classes combining stratigraphy, lithology and geomorphology.

Keywords: geomorphology, lithology, soil-forming factors, soil parent material, digital soil mapping, soil texture map, satellite imagery, stratigraphy, Linear Discriminant Analysis, decision tree, pedometrics


References

Aldana-Jague E, Heckrath G, Macdonald A, van Wesemael B, Van Oost K (2016) UAS-based soil carbon mapping using VIS-NIR (480–1000nm) multi-spectral imaging: Potential and limitations. Geoderma 275, 55–66.
UAS-based soil carbon mapping using VIS-NIR (480–1000nm) multi-spectral imaging: Potential and limitations.Crossref | GoogleScholarGoogle Scholar |

Boettinger J, Ramsey R, Bodily J, Cole N, Kienast-Brown S, Nield S, Saunders A, Stum A (2008) Landsat spectral data for digital soil mapping. In ‘Digital soil mapping with limited data’. (Eds AE Hartemink, A McBratney, M Mendonça-Santos) pp. 193–202. (Springer) https://doi.org/10.1007/978-1-4020-8592-5_16

Bonfatti BR, Demattê JAM, Marques KPP, Poppiel RR, Rizzo R, Mendes WdS, Silvero NEQ, Safanelli JL (2020) Digital mapping of soil parent material in a heterogeneous tropical area. Geomorphology 367, 107305
Digital mapping of soil parent material in a heterogeneous tropical area.Crossref | GoogleScholarGoogle Scholar |

Dobos E, Seres A, Vadnai P, Michéli E, Fuchs M, Láng V, Bertóti RD, Kovács K (2013) Soil parent material delineation using MODIS and SRTM data. Hungarian Geographical Bulletin 62, 133–156.

Drori R, Dan H, Sprintsin M, Sheffer E (2020) Precipitation-Sensitive Dynamic Threshold: A New and Simple Method to Detect and Monitor Forest and Woody Vegetation Cover in Sub-Humid to Arid Areas. Remote Sensing 12, 1231
Precipitation-Sensitive Dynamic Threshold: A New and Simple Method to Detect and Monitor Forest and Woody Vegetation Cover in Sub-Humid to Arid Areas.Crossref | GoogleScholarGoogle Scholar |

Dymond JR, Luckman PG (1994) Direct induction of compact rule-based classifiers for resource mapping. International Journal of Geographical Information Systems 8, 357–367.
Direct induction of compact rule-based classifiers for resource mapping.Crossref | GoogleScholarGoogle Scholar |

Eldeiry AA, Garcia LA (2010) Comparison of Ordinary Kriging, Regression Kriging, and Cokriging Techniques to Estimate Soil Salinity Using LANDSAT Images. Journal of Irrigation and Drainage Engineering 136, 355–364.
Comparison of Ordinary Kriging, Regression Kriging, and Cokriging Techniques to Estimate Soil Salinity Using LANDSAT Images.Crossref | GoogleScholarGoogle Scholar |

Gia Pham T, Kappas M, Van Huynh C, Hoang Khanh Nguyen L (2019) Application of ordinary kriging and regression kriging method for soil properties mapping in hilly region of Central Vietnam. ISPRS International Journal of Geo-Information 8, 147
Application of ordinary kriging and regression kriging method for soil properties mapping in hilly region of Central Vietnam.Crossref | GoogleScholarGoogle Scholar |

Gomez C, Gholizadeh A, Borůvka L, Lagacherie P (2016) Using legacy data for correction of soil surface clay content predicted from VNIR/SWIR hyperspectral airborne images. Geoderma 276, 84–92.
Using legacy data for correction of soil surface clay content predicted from VNIR/SWIR hyperspectral airborne images.Crossref | GoogleScholarGoogle Scholar |

Gray JM, Bishop TFA, Wilford JR (2016) Lithology and soil relationships for soil modelling and mapping. Catena 147, 429–440.
Lithology and soil relationships for soil modelling and mapping.Crossref | GoogleScholarGoogle Scholar |

Heung B, Bulmer CE, Schmidt MG (2014) Predictive soil parent material mapping at a regional-scale: A Random Forest approach. Geoderma 214–215, 141–154.
Predictive soil parent material mapping at a regional-scale: A Random Forest approach.Crossref | GoogleScholarGoogle Scholar |

Jasiewicz J, Stepinski TF (2013) Geomorphons — a pattern recognition approach to classification and mapping of landforms. Geomorphology 182, 147–156.
Geomorphons — a pattern recognition approach to classification and mapping of landforms.Crossref | GoogleScholarGoogle Scholar |

Kuhn, M, Weston, S, Keefer, C, Coulter, N (2012) Cubist models for regression. R package Vignette R package version 0.0 Available at https://mran.microsoft.com/snapshot/2016-09-04/web/packages/Cubist/vignettes/cubist.pdf

Kuhn  MWeston  SKeefer  CKuhn  MM (2020 ) https://CRAN.R-project.org/package=Cubist

Lacoste M, Lemercier B, Walter C (2011) Regional mapping of soil parent material by machine learning based on point data. Geomorphology 133, 90–99.
Regional mapping of soil parent material by machine learning based on point data.Crossref | GoogleScholarGoogle Scholar |

Lagacherie P, Holmes S (1997) Addressing geographical data errors in a classification tree for soil unit prediction. International Journal of Geographical Information Science 11, 183–198.
Addressing geographical data errors in a classification tree for soil unit prediction.Crossref | GoogleScholarGoogle Scholar |

Lawley, R (2014) ‘User guide: soil parent material 1 kilometre dataset.’ (British Geological Survey)

Legros J, Bonneric P (1979) Modelisation informatique de la repartition des sols dans le Parc Naturel Régional du Pilat. Annales de l’Université de Savoie 4, 63–68.

Loiseau T, Chen S, Mulder VL, Román Dobarco M, Richer-de-Forges AC, Lehmann S, Bourennane H, Saby NPA, Martin MP, Vaudour E, Gomez C, Lagacherie P, Arrouays D (2019) Satellite data integration for soil clay content modelling at a national scale. International Journal of Applied Earth Observation and Geoinformation 82, 101905
Satellite data integration for soil clay content modelling at a national scale.Crossref | GoogleScholarGoogle Scholar |

Ma Y, Minasny B, Malone BP, Mcbratney AB (2019) Pedology and digital soil mapping (DSM). European Journal of Soil Science 70, 216–235.
Pedology and digital soil mapping (DSM).Crossref | GoogleScholarGoogle Scholar |

Malone BP, Minasny B, McBratney AB (2009) Mapping continuous soil depth functions in the Edgeroi District, NSW, Australia, using terrain attributes and other environmental factors. In ‘Proceedings of geomorphometry 2009’ (Eds R Purves, T Hengl) pp. 90–97. Available at http://geomorphometry.org/Malone2009

McBratney AB, Mendonça Santos ML, Minasny B (2003) On digital soil mapping. Geoderma 117, 3–52.
On digital soil mapping.Crossref | GoogleScholarGoogle Scholar |

McGarry, D, Ward, WT, McBratney, AB (1989) ‘Soil Studies in the Lower Namoi Valley: Methods and Data. 1, The Edgeroi Data Set.’ (CSIRO Division of Soils)

McKenzie NJ, Ryan PJ (1999) Spatial prediction of soil properties using environmental correlation. Geoderma 89, 67–94.
Spatial prediction of soil properties using environmental correlation.Crossref | GoogleScholarGoogle Scholar |

Minty B, Franklin R, Milligan P, Richardson M, Wilford J (2009) The radiometric map of Australia. Exploration Geophysics 40, 325–333.
The radiometric map of Australia.Crossref | GoogleScholarGoogle Scholar |

Mora-Vallejo A, Claessens L, Stoorvogel J, Heuvelink GBM (2008) Small scale digital soil mapping in Southeastern Kenya. Catena 76, 44–53.
Small scale digital soil mapping in Southeastern Kenya.Crossref | GoogleScholarGoogle Scholar |

Oldeman LR, van Engelen VWP (1993) A world soils and terrain digital database (SOTER) — An improved assessment of land resources. Geoderma 60, 309–325.
A world soils and terrain digital database (SOTER) — An improved assessment of land resources.Crossref | GoogleScholarGoogle Scholar |

Padarian J, Minasny B, McBratney AB (2020) Machine learning and soil sciences: a review aided by machine learning tools. Soil (Göttingen) 6, 35–52.
Machine learning and soil sciences: a review aided by machine learning tools.Crossref | GoogleScholarGoogle Scholar |

Pebesma E, Heuvelink G (2016) Spatio-temporal interpolation using gstat. The R Journal 8, 204–218.
Spatio-temporal interpolation using gstat.Crossref | GoogleScholarGoogle Scholar |

Pebesma EJ (2004) Multivariable geostatistics in S: the gstat package. Computers & Geosciences 30, 683–691.
Multivariable geostatistics in S: the gstat package.Crossref | GoogleScholarGoogle Scholar |

Pracilio G, Adams ML, Smettem KRJ, Harper RJ (2006) Determination of Spatial Distribution Patterns of Clay and Plant Available Potassium Contents in Surface Soils at the Farm Scale using High Resolution Gamma Ray Spectrometry. Plant and Soil 282, 67–82.
Determination of Spatial Distribution Patterns of Clay and Plant Available Potassium Contents in Surface Soils at the Farm Scale using High Resolution Gamma Ray Spectrometry.Crossref | GoogleScholarGoogle Scholar |

Raymond OL, Liu S, Gallagher R, Zhang W, Highet LM (2014) Surface geology of Australia 1:1 million scale dataset 2012 edition. Available at https://ecat.ga.gov.au/geonetwork/srv/eng/catalog.search#/metadata/74619 [Verified 28 April 2021]

Roberts D, Wilford J, Ghattas O (2019) Exposed soil and mineral map of the Australian continent revealing the land at its barest. Nature Communications 10, 5297
Exposed soil and mineral map of the Australian continent revealing the land at its barest.Crossref | GoogleScholarGoogle Scholar | 31757967PubMed |

Ryan P, McKenzie N, O’Connell D, Loughhead A, Leppert P, Jacquier D, Ashton L (2000) Integrating forest soils information across scales: spatial prediction of soil properties under Australian forests. Forest Ecology and Management 138, 139–157.
Integrating forest soils information across scales: spatial prediction of soil properties under Australian forests.Crossref | GoogleScholarGoogle Scholar |

R Core Team (2013) R: A language and environment for statistical computing. Vienna, Austria

Triantafilis J, Earl N, Gibbs I (2016) Digital soil-class mapping across the Edgeroi district using numerical clustering and gamma-ray spectrometry data. Computing Ethics: A Multicultural Approach 187,

Triantafilis J, Gibbs I, Earl N (2013) Digital soil pattern recognition in the lower Namoi valley using numerical clustering of gamma-ray spectrometry data. Geoderma 192, 407–421.
Digital soil pattern recognition in the lower Namoi valley using numerical clustering of gamma-ray spectrometry data.Crossref | GoogleScholarGoogle Scholar |

Wallis GR (2019) ‘Narrabri 1:250 000 Geological Sheet SH-55–12.’ 1st edn. (Geological Survey of New South Wales: Sydney). Available at https://search.geoscience.nsw.gov.au/product/185 [Verified 1 May 2021]

Ward, W (1999) Soils and landscapes near Narrabri and Edgeroi, NSW, with data analysis and using fuzzy k-means. CSIRO Land and Water Technical Report No 22/99.

Wilford J (2012) A weathering intensity index for the Australian continent using airborne gamma-ray spectrometry and digital terrain analysis. Geoderma 183–184, 124–142.
A weathering intensity index for the Australian continent using airborne gamma-ray spectrometry and digital terrain analysis.Crossref | GoogleScholarGoogle Scholar |

Young RW, Young ARM, Price DM, Wray RAL (2002) Geomorphology of the Namoi alluvial plain, northwestern New South Wales. Australian Journal of Earth Sciences 49, 509–523.
Geomorphology of the Namoi alluvial plain, northwestern New South Wales.Crossref | GoogleScholarGoogle Scholar |