Register      Login
Soil Research Soil Research Society
Soil, land care and environmental research
Shopping Cart: ( empty )
You are here: Home > Journals > SR > SR15191
RESEARCH ARTICLE
Contents Vol 53(8)

Soil and Landscape Grid of Australia

M. J. Grundy A D , R. A. Viscarra Rossel B , R. D. Searle C , P. L. Wilson B , C. Chen B and L. J. Gregory B
+ Author Affiliations
- Author Affiliations

A CSIRO Agriculture 306 Carmody Road, St Lucia, Qld 4067, Australia.

B CSIRO Land and Water, PO Box 1666, Canberra, ACT 2601, Australia.

C CSIRO Land and Water, GPO Box 2583, Brisbane, Qld 4001, Australia.

D Corresponding author. Email: mike.grundy@csiro.au

Soil Research 53(8) 835-844 https://doi.org/10.1071/SR15191
Submitted: 7 July 2015  Accepted: 31 July 2015   Published: 12 October 2015

Abstract

The Soil and Landscape Grid of Australia (SLGA) is the first continental version of the GlobalSoilMap concept and the first nationally consistent, fine spatial resolution set of continuous soil attributes with Australia-wide coverage. The SLGA relies on digital soil mapping methods and integrates historical soil data, new measurement with spectroscopic sensors, novel spatial modelling and a web-service delivery architecture. The SLGA provides soil, regolith and landscape estimates at the centre point of 3 arcsecond grid cells (~90 × 90 m) across Australia. At each point, there are estimates of 11 soil attributes and confidence intervals for each estimate to a depth of 2 m or less, depth of regolith and a set of terrain descriptors. The information system also includes a library of mid-infrared spectra, an inference engine that allows estimation of additional soil parameters and an information model that enables users to access the system via web services. The explicit mapping of depth, bulk density and coarse fragments allows estimation of material stores and fluxes on a volumetric basis. The SLGA therefore has immediate applications in carbon, nitrogen and water process modelling. The map of regolith depth will find immediate application to studies of vadose zone processes, including solute transport, groundwater and nutrient fluxes beyond the root zone. Landscape attributes at 1 and 3 arcseconds are useful for a wide spectrum of ecological, hydrological and broader environmental applications. The SLGA can be accessed at no cost from www.csiro.au/soil-and-landscape-grid. It is managed and delivered as part of the Australian Soil Resource Information System (ASRIS).

Additional keywords: digital soil mapping, GlobalSoilMap, regolith, soil information systems, soil map disaggregation, spatial modelling.


References

Adams MA, Attiwill PM (1996) ‘Nutrition of eucalypts.’ (CSIRO: Melbourne)

Arrouays D, Grundy MG, Hartemink AE, Hempel JW, Heuvelink GBM, Hong SY, Lagacherie P, Lelyk G, McBratney AB, McKenzie NJ, Mendonça Santos ML, Minasny B, Montanarella L, Odeh IOA, Sanchez PA, Thompson JA, Zhang G-L (2014) GlobalSoilMap: toward a fine-resolution global grid of soil properties. In ‘Advances in agronomy’, Vol. 125. (Ed. DL Sparks) pp. 93–134. (Academic Press: San Diego, CA, USA)

Bishop TFA, McBratney AB, Laslett GM (1999) Modelling soil attribute depth functions with equal-area quadratic smoothing splines. Geoderma 91, 27–45.
Modelling soil attribute depth functions with equal-area quadratic smoothing splines.Crossref | GoogleScholarGoogle Scholar |

Burrough PA (1991) Soil information systems. In ‘Geographical information systems: principles and applications’. (Eds DJ Maguire, MF Goodchild, DW Rhind) pp. 153–169. (Longman and Wiley: New York)

Clifford D, Dobbie MJ, Searle R (2014) Non-parametric imputation of properties for soil profiles with sparse observations. Geoderma 232–234, 10–18.
Non-parametric imputation of properties for soil profiles with sparse observations.Crossref | GoogleScholarGoogle Scholar |

Connor JD, Bryan BA, Nolan M, Stock F, Gao L, Dunstall S, Graham P, Ernst A, Newth D, Grundy M, Hatfield-Dodds S (2015) Modelling Australian land use competition and ecosystem services with food price feedbacks at high spatial resolution. Environmental Modelling & Software 69, 141–154.
Modelling Australian land use competition and ecosystem services with food price feedbacks at high spatial resolution.Crossref | GoogleScholarGoogle Scholar |

de Caritat P, Lech M, McPherson A (2008) Geochemical mapping ‘down under’: selected results from pilot projects and strategy outline for the national geochemical survey of Australia. Geochemistry Exploration Environment Analysis 8, 301–312.
Geochemical mapping ‘down under’: selected results from pilot projects and strategy outline for the national geochemical survey of Australia.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXhtVCks77O&md5=c9a1e163c90d1fc5243ad65bccefb44eCAS |

Division of Land Research (1971) ‘Annual report 1970–71.’ (CSIRO: Melbourne)

Farr TG, Rosen PA, Caro E, Crippen R, Duren R, Hensley S, Kobrick M, Paller M, Rodriguez E, Roth L, Seal D, Shaffer S, Shimada J, Umland J, Werner M, Oskin M, Burbank D, Alsdorf D (2007) The Shuttle Radar Topography Mission. Reviews of Geophysics 45, RG2004
The Shuttle Radar Topography Mission.Crossref | GoogleScholarGoogle Scholar |

Gallant JC, Austin JM (2015) Derivation of terrain covariates for digital soil mapping in Australia. Soil Research 53, 895–906.

GlobalSoilMap Science Committee (2013) ‘GlobalSoilMap specifications: tiered GlobalSoilMap products. Release 2.3.’ (GlobalSoilMap Consortium)

Grundy M (2014) The new Australian grid: a multi-institutional template? In ‘GlobalSoilMap: basis of the global spatial soil information system’. (Eds D Arrouays, N McKenzie, J Hempel, AR de Forges, AB McBratney) pp. 73–77. (CRC Press: London)

Grundy MJ, Searle RD, Robinson JB (2012) An Australian soil grid: infrastructure and function. In ‘Digital soil assessments and beyond’. (Eds B Minasny, B Malone, A McBratney) pp. 459–464. (Taylor and Francis Group: London)

Hartemink AE, McBratney AB, Mendonça Santos ML (2008) ‘Digital soil mapping with limited data.’ (Springer: Dordrecht)

Heiner IJ, Grundy MJ (1994) ‘Land resources of the Ravenshoe–Mt Garnet area north Queensland Vol. 1. Land resource inventory QV94006.’ (Department of Primary Industries Queensland: Brisbane)

Henderson BL, Bui EN, Moran CJ, Simon DAP (2005) Australia-wide predictions of soil properties using decision trees. Geoderma 124, 383–398.
Australia-wide predictions of soil properties using decision trees.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2cXhtVKmtbbO&md5=85bf65dd9a18d538ff4b143f26c61af2CAS |

Hengl T, de Jesus JM, MacMillan RA, Batjes NH, Heuvelink GBM, Ribeiro E, Samuel-Rosa A, Kempen B, Leenaars JGB, Walsh MG, Gonzalez MR (2014) SoilGrids1km: global soil information based on automated mapping. PLoS One 9, e105992
SoilGrids1km: global soil information based on automated mapping.Crossref | GoogleScholarGoogle Scholar | 25171179PubMed |

Hewitt A, McKenzie N, Grundy M, Slater B (2008) Qualitative survey. In ‘Guidelines for surveying soil and land resources’. (Eds N McKenzie, M Grundy, R Webster, A Ringrose-Voase) pp. 285–306. (CSIRO Publishing: Melbourne)

Hicks W, Viscarra Rossel RA, Tuomi S (2015) Developing the Australian mid-infrared spectroscopic database using data from the Australian Soil Resource Information System. Soil Research 53, 922–931.

Hochman Z, Gobbett D, Holzworth D, McClelland T, van Rees H, Marinoni O, Garcia JN, Horan H (2012) Quantifying yield gaps in rainfed cropping systems: a case study of wheat in Australia. Field Crops Research 136, 85–96.
Quantifying yield gaps in rainfed cropping systems: a case study of wheat in Australia.Crossref | GoogleScholarGoogle Scholar |

Holmes KW, Griffin EA, Odgers NP (2015) Large-area spatial disaggregation of a mosaic of conventional soil maps: evaluation over Western Australia. Soil Research 53, 865–880.

Hutchinson MF (2007) ‘ANUDEM Version 5.2.’ (Fenner School of Environment and Society, Australian National University: Canberra) Available at: http://fennerschool.anu.edu.au/publications/software/anudem.php (accessed 27 March 2015).

Hutchinson MF (2008) Adding the Z dimension. In ‘The Handbook of Geographic Information Science’. (Eds John P. Wilson, A. Stewart Fotheringham) pp. 144–168. (Blackwell Publishing: Oxford, UK)

Jacquier DW, Wilson P, Griffin EA, Brough D (2012) ‘Soil Information Transfer and Evaluation System (SITES): database design and exchange protocols. Version 2.0.’ (CSIRO: Canberra, ACT)

Jones RJA, Houšková B, Bullock B, Montanarella L (2005) ‘Soil resources of Europe’, 2nd edn. (Office for Official Publications of the European Communities: Luxembourg)

Kidd D, Webb M, Malone B, Minasny B, McBratney A (2015) Eighty-metre resolution 3D soil-attribute maps for Tasmania, Australia. Soil Research 53, 932–955.

Lagacherie P, McBratney AB, Voltz M (2006) ‘Digital soil mapping: an introductory perspective.’ (Elsevier: Amsterdam)

Le Guillou F, Wetterlind W, Viscarra Rossel RA, Hicks W, Grundy M, Tuomi S (2015) How does grinding affect the mid-infrared spectra of soil and their multivariate calibrations to texture and organic carbon? Soil Research 53, 913–921.

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

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 |

McKenzie N, Jacquier D, Maschmedt D, Griffin E, Brough D (2012) ‘The Australian Soil Resource Information System (ASRIS) technical specifications. Revised version 1.6, June 2012.’ (CSIRO Australia: Canberra, ACT)

Moore ID, Gessler PE, Nielsen GA, Peterson GA (1993) Soil attribute prediction using terrain analysis. Soil Science Society of America Journal 57, 443–452.
Soil attribute prediction using terrain analysis.Crossref | GoogleScholarGoogle Scholar |

Moran CJ, Bui EN (2002) Spatial data mining for enhanced soil map modelling. International Journal of Geographical Information Science 16, 533–549.
Spatial data mining for enhanced soil map modelling.Crossref | GoogleScholarGoogle Scholar |

Northcote KH, Beckmann GG, Bettenay E, Churchward HM, Van Dijk DC, Dimmock GM, Hubble GD, Isbell RF, McArthur WM, Murtha GG, Nicolls KD, Paton TR, Thompson CH, Webb AA, Wright MJ (1960–1968) ‘Atlas of Australian soils, sheets 1 to 10. With explanatory data.’ (CSIRO and Melbourne University Press: Melbourne)

Odgers NP, Sun W, McBratney AB, Minasny B, Clifford D (2014) Disaggregating and harmonising soil map units through resampled classification trees. Geoderma 214–215, 91–100.
Disaggregating and harmonising soil map units through resampled classification trees.Crossref | GoogleScholarGoogle Scholar |

Odgers NP, Holmes KW, Griffin T, Liddicoat C (2015a) Derivation of soil-attribute estimations from legacy soil maps. Soil Research 53, 881–894.

Odgers NP, McBratney AB, Minasny B (2015b) Digital soil property mapping and uncertainty estimation using soil class probability rasters. Geoderma 237–238, 190–198.
Digital soil property mapping and uncertainty estimation using soil class probability rasters.Crossref | GoogleScholarGoogle Scholar |

Prescott JA (1950) A climatic index for the leaching factor in soil formation. Journal of Soil Science 1, 9–19.
A climatic index for the leaching factor in soil formation.Crossref | GoogleScholarGoogle Scholar |

Raupach MR, Rayner PJ, Barrett DJ, DeFries RS, Heimann M, Ojima DS, Quegan S, Schmullius CC (2005) Model–data synthesis in terrestrial carbon observation: methods, data requirements and data uncertainty specifications. Global Change Biology 11, 378–397.
Model–data synthesis in terrestrial carbon observation: methods, data requirements and data uncertainty specifications.Crossref | GoogleScholarGoogle Scholar |

Renzullo LJ, Barrett DJ, Marks AS, Hill MJ, Guerschman JP, Mu Q, Running SW (2008) Multi-sensor model-data fusion for estimation of hydrologic and energy flux parameters. Remote Sensing of Environment 112, 1306–1319.
Multi-sensor model-data fusion for estimation of hydrologic and energy flux parameters.Crossref | GoogleScholarGoogle Scholar |

Sachs J, Remans R, Smukler S, Winowiecki L, Andelman SJ, Cassman KG, Castle D, DeFries R, Denning G, Fanzo J, Jackson LE, Leemans R, Lehmann J, Milder JC, Naeem S, Nziguheba G, Palm CA, Pingali PL, Reganold JP, Richter DD, Scherr SJ, Sircely J, Sullivan C, Tomich TP, Sanchez PA (2010) Monitoring the world’s agriculture. Nature 466, 558–560.
Monitoring the world’s agriculture.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXpsFWks7Y%3D&md5=26fb3dc042dec0535143df0a805f93ccCAS | 20671691PubMed |

Sanchez PA, Ahamed S, Carré F, Hartemink AE, Hempel J, Huising J, Lagacherie P, McBratney AB, McKenzie NJ, Mendonça-Santos MdL, Minasny B, Montanarella L, Okoth P, Palm CA, Sachs JD, Shepherd KD, Vågen T-G, Vanlauwe B, Walsh MG, Winowiecki LA, Zhang G-L (2009) Digital soil map of the world. Science 325, 680–681.
Digital soil map of the world.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXhtVSrs7bN&md5=7b7c33dd307eecdf261b292bf49633d6CAS | 19661405PubMed |

Scull P, Franklin J, Chadwick OA, McArthur D (2003) Predictive soil mapping: a review. Progress in Physical Geography 27, 171–197.
Predictive soil mapping: a review.Crossref | GoogleScholarGoogle Scholar |

Searle R (2014) The Australian site data collation to support the GlobalSoilMap. In ‘GlobalSoilMap: basis of the global spatial soil information system’. (Eds D Arrouays, N McKenzie, J Hempel, AR de Forges, AB McBratney) pp. 127–132. (CRC Press: London)

Simons B, Wilson P, Ritchie A, Jacquier D, Vleeshouwer J (2014) An Australian–New Zealand standard for exchange of soil and landscape data: ANZSoilML v2.0. In ‘20th World Congress of Soil Science’. (IUSS: Jeju, Korea)

Soil Survey Staff (2014) ‘Web soil survey.’ USDoA Natural Resources Conservation Service. Available at: http://websoilsurvey.nrcs.usda.gov/ (accessed 27 March 2015).

Soils Research Development and Extension Working Group (2011) ‘A stocktake of Australia’s current investment in soils research, development and extension: a snapshot for 2010–11.’ (Department of Agriculture, Fisheries and Forestry: Canberra) Available at: http://nrmonline.nrm.gov.au/catalog/mql:2563 (accessed 24 December 2014).

Speight JG (2009) Landform. In ‘Australian soil and land survey field handbook’. 3rd edn. (Ed. National Committee on Soil and Terrain) pp. 15–72. (CSIRO Publishing: Melbourne)

Viscarra Rossel RA (2011) Fine-resolution multiscale mapping of clay minerals in Australian soils measured with near infrared spectra. Journal of Geophysical Research: Earth Surface 116, F04023
Fine-resolution multiscale mapping of clay minerals in Australian soils measured with near infrared spectra.Crossref | GoogleScholarGoogle Scholar |

Viscarra Rossel RA, Chen C (2011) Digitally mapping the information content of visible–near infrared spectra of surficial Australian soils. Remote Sensing of Environment 115, 1443–1455.
Digitally mapping the information content of visible–near infrared spectra of surficial Australian soils.Crossref | GoogleScholarGoogle Scholar |

Viscarra Rossel RA, Webster R (2012) Predicting soil properties from the Australian soil visible–near infrared spectroscopic database. European Journal of Soil Science 63, 848–860.
Predicting soil properties from the Australian soil visible–near infrared spectroscopic database.Crossref | GoogleScholarGoogle Scholar |

Viscarra Rossel RA, Adamchuk VI, Sudduth KA, McKenzie NJ, Lobsey C (2011) Proximal soil sensing: an effective approach for soil measurements in space and time. In ‘Advances in agronomy’. Vol. 113. (Ed. LS Donald) pp. 243–291. (Academic Press: San Diego, CA, USA)

Viscarra Rossel RA, Chen C, Grundy MJ, Searle R, Clifford D, Campbell PH (2015) The Australian three-dimensional soil grid: Australia’s contribution to the GlobalSoilMap project. Soil Research 53, 845–864.

Viscarra Rossel RA, Webster R, Bui EN, Baldock JA (2014) Baseline map of organic carbon in Australian soil to support national carbon accounting and monitoring under climate change. Global Change Biology.
Baseline map of organic carbon in Australian soil to support national carbon accounting and monitoring under climate change.Crossref | GoogleScholarGoogle Scholar | 24599716PubMed |

White A, Sparrow B, Leitch E, Foulkes J, Flitton R, Lowe A, Caddy-Retalic S (2012) ‘AUSPLOTS rangelands survey protocols manual.’ (The University of Adelaide Press: Adelaide)

Wilson P, Ringrose-Voase AJ, Jacquier DW, Gregory L, Webb M, Wong MTF, Powell B, Brough D, Hill J, Lynch B, Schoknecht N, Griffin EA (2009) Land and soil resources in northern Australia. In ‘Northern Australia Land and Water Science Review 2009’. (Ed. P Stone) pp. 2-1–2-47. (Northern Australia Land and Water Taskforce: Canberra)

Wilson P, Simons B, Ritchie A (2014) Opportunities for information model driven exchange and delivery of GlobalSoilMap data and related products. In ‘GlobalSoilMap’. (Eds D Arrouays, N McKenzie, J Hempel, AR de Forges, AB McBratney) pp. 473–476. (CRC Press: London)