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RESEARCH ARTICLE
Contents Vol 47(7)

Field level digital soil mapping of cation exchange capacity using electromagnetic induction and a hierarchical spatial regression model

John Triantafilis A C , Scott Mitchell Lesch B , Kevin La Lau A and Sam Mostyn Buchanan A
+ Author Affiliations
- Author Affiliations

A School of Biological Earth and Environmental Sciences, The University of New South Wales, NSW 2052, Sydney, Australia.

B Statistical Consulting Collaboratory, U.C. Riverside, 2683 Stat-Comp, 900 University Ave, Riverside, CA 92521, USA.

C Corresponding author. Email: j.triantafilis@unsw.edu.au

Australian Journal of Soil Research 47(7) 651-663 https://doi.org/10.1071/SR08240
Submitted: 26 October 2008  Accepted: 7 July 2009   Published: 6 November 2009

Abstract

At the field level the demand for spatial information of soil properties is rapidly increasing owing to its requirements in precision agriculture and soil management. One of the most important properties is the cation exchange capacity (CEC, cmol(+)/kg) because it is an index of the shrink–swell potential and hence is a measure of soil structural resilience to tillage. However, CEC is time-consuming and expensive to measure. Various ancillary datasets and statistical methods can be used to predict CEC, but there is little scientific literature which implements this approach to map CEC or addresses the issue of the amount of ancillary data required to maximise precision and minimise bias of spatial prediction at the field level. We compare a standard least-squares multiple linear regression (MLR) model which includes 2 proximally sensed (EM38 and EM31), 3 remotely sensed (Red, Green and Blue spectral brightness), and 2 trend surface (Easting and Northing) variables as ancillary data or independent variables, and a stepwise MLR model which only includes the statistically valid EM38 signal data and the Easting trend surface vector. The latter is used as the basis for developing a hierarchical spatial regression model to predict CEC. The reliability of the model is analysed by comparing prediction precision (root mean square error) and bias (mean error) using degraded EM38 transect spacing (i.e. 96, 144, 192, 240, and 288 m) and comparing these with predictions achieved with the 48-m spacing. We conclude that the EM38 data available on the 96- and 144-m spacing are suitable at a reconnaissance level (i.e. broad-scale farming) and 24- or 48-m spacing are suitable at smaller levels where detailed information is necessary for siting the location of water reservoirs. In terms of soil management, CEC predictions determine where suitable subsoil exists for the purpose of soil profile inversion to improve the structural resilience of a topsoil that is susceptible to dispersion and surface crusting.

Additional keywords: electromagnetic (EM) induction, EM38, EM31, digital soil mapping, multiple linear regression (MLR), hierarchical spatial regression (HSR), ordinary kriging (OK).


Acknowledgments

The Australian Cotton Research and Development Corporation and Australian Cotton Cooperative Research Centre provided the core funding (CRC11C). The MESS survey, soil coring and laboratory analysis were funded by the Australian Federal Government Natural Heritage Trust (NW0688.99). We acknowledge the support of the Coordinating Committee of lower Namoi valley Water Users Association in obtaining these funds. We thank the landholder who allowed access to the study field. We acknowledge Mr Andrew Huckel who carried out the MESS survey and Dr Mohammad Faruque Ahmed for collecting and preparing the soil samples for determination of CEC.


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